https://www.cazypedia.org/api.php?action=feedcontributions&feedformat=atom&user=Alicia+Lammerts+van+BuerenCAZypedia - User contributions [en-ca]2026-05-06T00:12:43ZUser contributionsMediaWiki 1.35.10https://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_50&diff=9990Carbohydrate Binding Module Family 502014-06-17T18:44:00Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Takayuki Ohnuma^^^ and ^^^Toki Taira^^^ <br />
* [[Responsible Curator]]: ^^^Takayuki Ohnuma^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM50.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
CBM50 modules are also known as LysM domains. They bind to the N-acetylglucosamine residues in bacterial peptidoglycans and in chitin. For example CBM50 of ''Lactococcus lactis'' ''N''-acetylglucosaminidase AcmA was shown to bind to the glycan chain of bacterial peptidoglycans, a β-1,4 linked heteropolymer of alternating ''N''-acetylglucosamine (GlcNAc) and ''N''-acetylmuramic acid (MurNAc) <cite>Steen2003</cite>. A CBM50 module from ''Pteris ryukyuensis'' chitinase-A (PrChi-A) was demonstrated to bind to chitin, a β-1,4-linked homopolymer of GlcNAc <cite>Onaga2008</cite>. From isothermal titration calorimetry, the CBM50 module from PrChi-A was found to bind to (GlcNAc)<sub>n</sub> (n=4,5) with the binding stoichiometry of 1:1, whereas no significant binding heat was observed for the binding to (GlcNAc)<sub>2</sub> <cite>Ohnuma2008</cite>. The binding site of the CBM50 module can accommodate at least three saccharide units.<br />
<br />
== Structural Features ==<br />
CBM50 modules are about 50 amino acids long. The three-dimensional structures of three CBM50 modules attached to carbohydrate-active enzymes have been deposited in the Protein Data Bank (PDB entries: 1E0G <cite>Bateman2000</cite>, 2MKX and 4PXV). The CBM50 modules have a βααβ fold with the two helices packing against one side of the two-stranded antiparallel β-sheet. Although no crystal structure of the CBM50 module in complex with the ligand has been determined yet, Ohnuma ''et al''. first identified the chitin oligosaccharide binding site of the CBM50 module from PrChi-A based on the NMR titration experiments <cite>Ohnuma2008</cite>. The chitin oligosaccharide binding site was estimated to be located in a shallow groove formed by the N-terminal part of helix 1, the loop between strand 1 and helix 1, the C-terminal part of helix 2, and the loop between helix 2 and strand 2.<br />
<br />
== Functionalities == <br />
CBM50 modules are generally found in bacterial lysins including muramidase <cite>Chu1992</cite>, ''N''-acetylglucosaminidase <cite>Steen2003</cite>, γ-D-glutamate-meso-diaminopimelate muropeptidase <cite>Margot1999</cite> and ''N''-acetylmuramoyl-L-alanine amidase <cite>Kajimura2005</cite>. The CBM50 modules in lysins are shown to bind to bacterial peptidoglycan and involved in cell division by localizing these enzymes to the divisional site <cite>Visweswaran2013</cite>. CBM50 modules were also found in family GH18 chitinases <cite>Onaga2008 Gruger2011</cite>, and contribute to the antifungal activity of the enzymes through their binding ability to chitinous component of the fungal cell wall. CBM50 modules are found not only in carbohydrate-active enzymes but also in LysM-containing plant cell surface receptors for chitin oligosaccharides and their derivatives <cite>Kaku2006 Limpens2003</cite> and fungal effectors <cite>Bolton2008</cite>. The receptor proteins are involved in plant-microbe interactions upon symbiosis or infection.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
CBM50s are also known as LysM domains. The LysM domain was first identified in lysozyme from ''Bacillus phage'' f29 <cite>Garvey1986</cite>. LysM domains were first classified as a CBM in 2008 after demonstrating chitin oligosaccharide binding by an ''N''-terminal LysM domain from ''Pteris ryukyuensis'' chitinase-A <cite>Ohnuma2008</cite>. <br />
;First Structural Characterization<br />
The first three-dimensional structure of CBM50 module was determined for the LysM domain from ''E. coli'' membrane-bond lytic murein transglycosylase D (MltD) (PDB entry: 1E0G) by NMR spectroscopy <cite>Bateman2000</cite>. <br />
<br />
== References ==<br />
<biblio><br />
#Steen2003 pmid=12684515<br />
#Onaga2008 pmid=18310304<br />
#Ohnuma2008 pmid=18083709<br />
#Bateman2000 pmid=10843862<br />
#Chu1992 pmid=1347040 <br />
#Margot1999 pmid=10206711<br />
#Kajimura2005 pmid=16262792<br />
#Visweswaran2013 pmid=23951292<br />
#Gruger2011 pmid=20843785<br />
#Kaku2006 pmid=16829581<br />
#Limpens2003 pmid=12947035<br />
#Bolton2008 pmid=18452583<br />
#Garvey1986 pmid=3027653<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM050]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_50&diff=9989Carbohydrate Binding Module Family 502014-06-17T18:40:59Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Takayuki Ohnuma^^^ and ^^^Toki Taira^^^ <br />
* [[Responsible Curator]]: ^^^Takayuki Ohnuma^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM50.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
CBM50 modules are also known as LysM domains. They bind to the N-acetylglucosamine residues in bacterial peptidoglycans and in chitin. For example CBM50 of ''Lactococcus lactis'' ''N''-acetylglucosaminidase AcmA was shown to bind to the glycan chain of bacterial peptidoglycans, a β-1,4 linked heteropolymer of alternating ''N''-acetylglucosamine (GlcNAc) and ''N''-acetylmuramic acid (MurNAc) <cite>Steen2003</cite>. A CBM50 module from ''Pteris ryukyuensis'' chitinase-A (PrChi-A) was demonstrated to bind to chitin, a β-1,4-linked homopolymer of GlcNAc <cite>Onaga2008</cite>. From isothermal titration calorimetry, the CBM50 module from PrChi-A was found to bind to (GlcNAc)<sub>n</sub> (n=4,5) with the binding stoichiometry of 1:1, whereas no significant binding heat was observed for the binding to (GlcNAc)<sub>2</sub> <cite>Ohnuma2008</cite>. The binding site of the CBM50 module can accommodate at least three saccharide units.<br />
<br />
== Structural Features ==<br />
CBM50 modules are about 50 amino acids long. The three-dimensional structures of three CBM50 modules attached to carbohydrate-active enzymes have been deposited in the Protein Data Bank (PDB entries: 1E0G <cite>Bateman2000</cite>, 2MKX and 4PXV). The CBM50 modules have a βααβ fold with the two helices packing against one side of the two-stranded antiparallel β-sheet. Although no crystal structure of the CBM50 module in complex with the ligand has been determined yet, Ohnuma ''et al''. first identified the chitin oligosaccharide binding site of the CBM50 module from PrChi-A based on the NMR titration experiments <cite>Ohnuma2008</cite>. The chitin oligosaccharide binding site was estimated to be located in a shallow groove formed by the N-terminal part of helix 1, the loop between strand 1 and helix 1, the C-terminal part of helix 2, and the loop between helix 2 and strand 2.<br />
<br />
== Functionalities == <br />
CBM50 modules are generally found in bacterial lysins including muramidase <cite>Chu1992</cite>, ''N''-acetylglucosaminidase <cite>Steen2003</cite>, γ-D-glutamate-meso-diaminopimelate muropeptidase <cite>Margot1999</cite> and ''N''-acetylmuramoyl-L-alanine amidase <cite>Kajimura2005</cite>. The CBM50 modules in lysins are shown to bind to bacterial peptidoglycan and involved in cell division by localizing these enzymes to the divisional site <cite>Visweswaran2013</cite>. CBM50 modules were also found in family GH18 chitinases <cite>Onaga2008 Gruger2011</cite>, and contribute to the antifungal activity of the enzymes through their binding ability to chitinous component of the fungal cell wall. CBM50 modules are found not only in carbohydrate-active enzymes but also in LysM-containing plant cell surface receptors for chitin oligosaccharides and their derivatives <cite>Kaku2006 Limpens2003</cite> and fungal effectors <cite>Bolton2008</cite>. The receptor proteins are involved in plant-microbe interactions upon symbiosis or infection.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
CBM50 is also known as LysM domains. The LysM domain was first identified in lysozyme from ''Bacillus phage'' f29 <cite>Garvey1986</cite>. LysM domains were first classified as a CBM in 2008 after demonstrating chitin oligosaccharide binding by an ''N''-terminal LysM domain from ''Pteris ryukyuensis'' chitinase-A <cite>Ohnuma2008</cite>. <br />
;First Structural Characterization<br />
The first three-dimensional structure of CBM50 module was determined for the LysM domain from ''E. coli'' membrane-bond lytic murein transglycosylase D (MltD) (PDB entry: 1E0G) by NMR spectroscopy <cite>Bateman2000</cite>. <br />
<br />
== References ==<br />
<biblio><br />
#Steen2003 pmid=12684515<br />
#Onaga2008 pmid=18310304<br />
#Ohnuma2008 pmid=18083709<br />
#Bateman2000 pmid=10843862<br />
#Chu1992 pmid=1347040 <br />
#Margot1999 pmid=10206711<br />
#Kajimura2005 pmid=16262792<br />
#Visweswaran2013 pmid=23951292<br />
#Gruger2011 pmid=20843785<br />
#Kaku2006 pmid=16829581<br />
#Limpens2003 pmid=12947035<br />
#Bolton2008 pmid=18452583<br />
#Garvey1986 pmid=3027653<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM050]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_50&diff=9988Carbohydrate Binding Module Family 502014-06-17T18:37:33Z<p>Alicia Lammerts van Bueren: edits of cbm50 page</p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Takayuki Ohnuma^^^ and ^^^Toki Taira^^^ <br />
* [[Responsible Curator]]: ^^^Takayuki Ohnuma^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM50.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
CBM50 modules are also known as LysM domains. They often occur in repeats and bind to the N-acetylglucosamine residues in bacterial peptidoglycans and in chitin. For example CBM50 of ''Lactococcus lactis'' ''N''-acetylglucosaminidase AcmA was shown to bind to the glycan chain of bacterial peptidoglycans, a β-1,4 linked heteropolymer of alternating ''N''-acetylglucosamine (GlcNAc) and ''N''-acetylmuramic acid (MurNAc) <cite>Steen2003</cite>. A CBM50 module from ''Pteris ryukyuensis'' chitinase-A (PrChi-A) was demonstrated to bind to chitin, a β-1,4-linked homopolymer of GlcNAc <cite>Onaga2008</cite>. From isothermal titration calorimetry, the CBM50 module from PrChi-A was found to bind to (GlcNAc)<sub>n</sub> (n=4,5) with the binding stoichiometry of 1:1, whereas no significant binding heat was observed for the binding to (GlcNAc)<sub>2</sub> <cite>Ohnuma2008</cite>. The binding site of the CBM50 module can accommodate at least three saccharide units.<br />
<br />
== Structural Features ==<br />
CBM50 modules are about 50 amino acids long. The three-dimensional structures of three CBM50 modules attached to carbohydrate-active enzymes have been deposited in the Protein Data Bank (PDB entries: 1E0G <cite>Bateman2000</cite>, 2MKX and 4PXV). The CBM50 modules have a βααβ fold with the two helices packing against one side of the two-stranded antiparallel β-sheet. Although no crystal structure of the CBM50 module in complex with the ligand has been determined yet, Ohnuma ''et al''. first identified the chitin oligosaccharide binding site of the CBM50 module from PrChi-A based on the NMR titration experiments <cite>Ohnuma2008</cite>. The chitin oligosaccharide binding site was estimated to be located in a shallow groove formed by the N-terminal part of helix 1, the loop between strand 1 and helix 1, the C-terminal part of helix 2, and the loop between helix 2 and strand 2.<br />
<br />
== Functionalities == <br />
CBM50 modules are generally found in bacterial lysins including muramidase <cite>Chu1992</cite>, ''N''-acetylglucosaminidase <cite>Steen2003</cite>, γ-D-glutamate-meso-diaminopimelate muropeptidase <cite>Margot1999</cite> and ''N''-acetylmuramoyl-L-alanine amidase <cite>Kajimura2005</cite>. The CBM50 modules in lysins are shown to bind to bacterial peptidoglycan and involved in cell division by localizing these enzymes to the divisional site <cite>Visweswaran2013</cite>. CBM50 modules were also found in family GH18 chitinases <cite>Onaga2008 Gruger2011</cite>, and contribute to the antifungal activity of the enzymes through their binding ability to chitinous component of the fungal cell wall. CBM50 modules are found not only in carbohydrate-active enzymes but also in LysM-containing plant cell surface receptors for chitin oligosaccharides and their derivatives <cite>Kaku2006 Limpens2003</cite> and fungal effectors <cite>Bolton2008</cite>. The receptor proteins are involved in plant-microbe interactions upon symbiosis or infection.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
CBM50 is also known as LysM domains. The LysM domain was first identified in lysozyme from ''Bacillus phage'' f29 <cite>Garvey1986</cite>. LysM domains were first classified as a CBM in 2008 after demonstrating chitin oligosaccharide binding by an ''N''-terminal LysM domain from ''Pteris ryukyuensis'' chitinase-A <cite>Ohnuma2008</cite>. <br />
;First Structural Characterization<br />
The first three-dimensional structure of CBM50 module was determined for the LysM domain from ''E. coli'' membrane-bond lytic murein transglycosylase D (MltD) (PDB entry: 1E0G) by NMR spectroscopy <cite>Bateman2000</cite>. <br />
<br />
== References ==<br />
<biblio><br />
#Steen2003 pmid=12684515<br />
#Onaga2008 pmid=18310304<br />
#Ohnuma2008 pmid=18083709<br />
#Bateman2000 pmid=10843862<br />
#Chu1992 pmid=1347040 <br />
#Margot1999 pmid=10206711<br />
#Kajimura2005 pmid=16262792<br />
#Visweswaran2013 pmid=23951292<br />
#Gruger2011 pmid=20843785<br />
#Kaku2006 pmid=16829581<br />
#Limpens2003 pmid=12947035<br />
#Bolton2008 pmid=18452583<br />
#Garvey1986 pmid=3027653<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM050]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_28&diff=9922Carbohydrate Binding Module Family 282014-05-16T07:45:36Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Shinya Fushinobu^^^<br />
* [[Responsible Curator]]: ^^^Shinya Fushinobu^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM28.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
This module was first classified in 2002 by a characterization study of the C-terminal module in [[GH5]] Cel5A from ''Bacillus'' sp. 1139 (''Bsp''CBM28) <cite>Boraston2002</cite>. All known CBM28s are so far derrived from bacterial origins, mostly attached to cellulosomal endoglucanases in tandem with [[CBM17]]. They bind non-crystalline (or amorphous) part of cellulose, cellooligosaccharides, or &beta;-1,3-1,4-glucans <cite>Boraston2002 Boraston2003</cite>.<br />
<br />
== Structural Features ==<br />
[[Image:CBM28-17-4.png|'''Figure 1:''' CBM28 ([{{PDBlink}}3aci 3aci]) <cite>Tsukimoto2010</cite> in comparison with CBM17 ([{{PDBlink}}1j84 1j84]) <cite>Notenboom2011</cite> and CBM4 ([{{PDBlink}}1gu3 1gu3]) <cite>Boraston2002-2</cite>. Sugars of cellooligosaccharides (cellopentaose or cellotetraose) are designated as A-E from the non-reducing end to the reducing end. Ca<sup>2+</sup> ions in CBM28 and CBM17 are shown as green spheres in the ribbon representations (upper). Important residues in the cleft are colored yellow (aromatic), red (acidic), blue (basic), and green (neutral) on the molecular surfaces (lower). |frame|right]]<br />
<br />
CBM28s have a &beta;-sandwich fold (approximately 200 amino acids) that is similar to [[CBM17]] and [[CBM4]] ('''Figure 1'''). The module has a straight cleft that binds a cellulose glycan chain at the concave face of the &beta;-sandwich fold. A Ca<sup>2+</sup> ion is bound on the back side of molecule. The Ca<sup>2+</sup> ion is not involved in ligand binding but appears to play a structural stabilization role. These modules are typical endo-type [[Carbohydrate-binding_modules#Types|Type B CBMs]] that accommodate a single glycan chain in an open cleft. '''Figure 1''' shows the cellopentaose complex structure ([{{PDBlink}}3aci 3aci]) of CBM28 in [[GH5]] Cel5A from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1499 ''Clostridium josui''] (''Cj''CBM28). The long binding cleft runs at the center of the molecule. Therefore, the binding pocket location of CBM28 is on the concave face (side) of the &beta;-sandwich fold, not within the variable loop region ([[Carbohydrate-binding_modules#Fold|CBM Fold]]). The shallow cleft of CBM28 binds one side of the cellooligosaccharides (face-on) in contrast with the case of [[CBM4]] (side-on). There are at at least five subsites (A-E from the non-reducing end to the reducing end) in ''Cj''CBM28. Interestingly, the direction of the cellooligosaccharides bound to CBM28 is opposite to those in [[CBM17]] and [[CBM4]]. Subsites B, C, and E form stacking interactions with aromatic residues (W78, W129, and F128 in ''Cj''CBM28). The flanking hydroxyl groups are extensively recognized by direct or water-mediated hydrogen bonds. Therefore, CBM28 has a relatively wide cleft.<br />
<br />
<br />
== Functionalities == <br />
CBM28s are thought to target catalytic modules (endoglucanases) to non-crystalline region of cellulose. Deletion mutants of CBM28 in Cel5A from ''Bacillus'' sp. 1139 showed significantly decreased amounts of the soluble products from amorphous cellulose <cite>Boraston2003</cite>. They are exclusively associated with [[GH5]] endo-&beta;-1,4-glucanases and a survey using the [http://www.ahv.dk/index.php/bioinformatic/cazy-tools/gh-cbm GH-CBM tool] shows that CBM28s are not associated with other GH family domains. As a typical endo-type (Type B) CBM, CBM28s show the <i>K</i><sub>a</sub> values of 0.7-5.2 &times;10<sup>4</sup> M<sup>-1</sup> for the binding of cellooligosaccharides (cellotetraose to cellohexaose), and it is enthalpically driven <cite>Boraston2002 Araki2009</cite>. ''Bsp''CBM28 binds amorphous (regenerated) cellulose with high-affinity (<i>K</i><sub>a</sub> = 9.9 &times;10<sup>5</sup> M<sup>-1</sup>) and low-affinity (<i>K</i><sub>a</sub> = 2.1 &times;10<sup>4</sup> M<sup>-1</sup>) cites <cite>Boraston2003</cite>. A novel application of CBM28 molecules was recently published where ''Bsp''CBM28 was used as a marker to identify amorphous regions in cellulose in photoactivated localization microscopy (PALM) studies <cite>Fox2013</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
The first identified member is the C-terminal module in Cel5A from ''Bacillus'' sp. 1139 (''Bsp''CBM28) <cite>Boraston2002</cite><br />
<br />
;First Structural Characterization<br />
Partial assignment of the NMR data of a CBM28 in Cel5I from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1521 ''Clostridium cellulolyticum''] was reported in 2002 <cite>Mosbah2002</cite> but its three-dimensional structure is not reported yet. The first crystal structure was reported in 2004 for ''Bsp''CBM28 in apo form ([{{PDBlink}}1uww 1uww]) <cite>Jamal2004</cite>. The first ligand complex structures were reported in 2010 for CBM28 in Cel5A from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1499 ''C. josui''] (''Cj''CBM28) ([{{PDBlink}}3acf 3acf] [{{PDBlink}}3acg 3acg] [{{PDBlink}}3ach 3ach] [{{PDBlink}}3aci 3aci]) <cite>Tsukimoto2010</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#Boraston2002 pmid=11743880<br />
#Boraston2003 pmid=12427734<br />
#Tsukimoto2010 pmid=20159017<br />
#Notenboom2011 pmid=11733998<br />
#Boraston2002-2 pmid=12079353<br />
#Araki2009 pmid=19420681<br />
<br />
#Fox2013 pmid=23563526<br />
#Mosbah2002 pmid=12153043<br />
#Jamal2004 pmid=15136030<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM028]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_42&diff=9921Carbohydrate Binding Module Family 422014-05-16T07:45:03Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Shinya Fushinobu^^^<br />
* [[Responsible Curator]]: ^^^Shinya Fushinobu^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM42.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
This module was originally identified as a non-catalytic xylan-binding domain in [[GH54]] &alpha;-L-arabinofuranosidase from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=51453 ''Trichoderma reesei''] PC-3-7 <cite>Nogawa1999</cite>. In 2004, it was found to be a CBM specific for an L-arabinofuranosyl group because L-arabinofuranose molecules were bound to a non-catalytic domain of [[GH54]] &alpha;-L-arabinofuranosidase B from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=40384 ''Aspergillus kawachii''] (AkAbfB) <cite>Miyanaga2004</cite>. CBM42 members have multivalent (usually divalent or trivalent) binding ability to non-reducing end L-arabinofuranosyl residues, which are present in plant polysaccharides (hemicelluloses) such as arabinoxylan, arabinan, and arabinogalactan. Most of CBM42s are associated with &alpha;-L-arabinofuranosidases from fungi ([[GH54]]) or bacteria ([[GH43]]). <br />
<br />
== Structural Features ==<br />
[[Image:CBM42.png|'''Figure 1:''' CBM42 of &alpha;-L-arabinofuranosidase B from ''A. kawachii'' in complex with &alpha;-L-arabinofuranosyl-&alpha;-1,2-xylobiose (2D44). The &alpha;-domain is non-functional. |frame|right]]<br />
<br />
CBM42s have a &beta;-trefoil fold that is similar to [[CBM13]] and R(ricin)-type lectins ('''Figure 1'''). The module has a sequential 3-fold internal repeat of approximately 45 amino acid residues comprising three subdomains. The three subdomains are denoted as &alpha;, &beta;, and &gamma;. Each subdomain contains a discrete ligand binding site, but one of the three subdomains sometimes loses its function due to mutations at critical residues for ligand binding. CBM42s are typical [[Carbohydrate-binding_modules#Types|Type C CBMs]] that bind termini of glycans with pocket-type binding sites for short oligosaccharides. The binding pockets are small but can accommodate the branched side chain L-arabinofuranosyl moiety attached to the xylan backbone of arabinoxylans <cite>Miyanaga2006</cite>. The binding sites are located at side pockets of the triangular structure of the &beta;-trefoil fold. Residues important for the binding to a non-reducing end L-arabinofuranosyl group are as follows: an aspartate forming hydrogen bonds to the O2 and O3 hydroxyls, a histidine forming a hydrogen bond to the O5 hydroxyl, and two aromatic residues (tyrosine, tryptophan, or phenylalanine) stacking to the furanose sugar ('''Figure 1'''). They are D425, H416, Y417 and Y456 in the &beta;-subdomain of AkAbfB and are conserved in functional CBM42 subdomains.<br />
<br />
Several crystal structures including complex structures with compounds containing an L-arabinofuranosyl group are available. For example, AkAbfB (&alpha;-subdomain is non-functional) ([{{PDBlink}}1wd3 1wd3] [{{PDBlink}}1wd4 1wd4]) <cite>Miyanaga2004</cite>, ([{{PDBlink}}2d43 2d43] [{{PDBlink}}2d44 2d44]) <cite>Miyanaga2006</cite>; Exo-1,5-&alpha;-L-arabinofuranosidase from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=33903 ''Sreptomyces avermitilis''] (all subdomains are functional) ([{{PDBlink}}3akf 3akf] [{{PDBlink}}3akg 3akg] [{{PDBlink}}3akh 3akh] [{{PDBlink}}3aki 3aki]) <cite>Fujimoto2010</cite>; CBM42A in Cthe_0015 from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1515 ''Clostridium thermocellum''] (&beta;-subdomain is non-functional) ([{{PDBlink}}3kmv 3kmv]) <cite>Ribeiro2010</cite>.<br />
<br />
== Functionalities == <br />
CBM42s are thought to target catalytic modules (usually &alpha;-L-arabinofuranosidases) to hemicelluloses that have L-arabinofuranosyl termini or branches. Mutations at the binding sites of CBM42 significantly reduced the catalytic activity toward natural polysaccharides in these enzymes, whereas the activity toward ''p''-nitrophenyl &alpha;-L-arabinofuranoside was not affected <cite>Miyanaga2006 Ribeiro2010</cite>. These modules are commonly associated with &alpha;-L-arabinofuranosidases or exo-arabinanases of [[GH2]], [[GH43]], [[GH54]], [[GH93]], or non-classified GHs <cite>Ribeiro2010</cite>. A survey using the [http://www.ahv.dk/index.php/bioinformatic/cazy-tools/gh-cbm GH-CBM tool] shows that CBM42s are also associated with [[GH16]] or [[GH30]]. As a typical exo-type (Type C) CBM, the CBM42 in AkAbfB shows relatively low binding affinities to L-arabinofuranose-containing oligosaccharides with <i>K</i><sub>a</sub> values of 1~5 &times;10<sup>3</sup> M<sup>-1</sup>. <cite>Miyanaga2006</cite>. In a novel application of CBM42 molecules, a CBM42 was fused to a feruloyl esterase to create a chimeric enzyme with enhanced thermostability and exhibited a four-fold higher activity on insoluble arabinoxylan <cite>Koseki2010</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
The L-arabinofuranose-binding function of CBM42 was first suggested by crystallography of &alpha;-L-arabinofuranosidase B from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=40384 ''Aspergillus kawachii''] (AkAbfB) <cite>Miyanaga2004</cite>.<br />
;First Structural Characterization<br />
The first structure of CBM42 was revealed in 2004 in the x-ray crystal structure of AkAbfB in complex with arabinose as a full-length structure with a catalytic [[GH54]] domain [{{PDBlink}}1wd4 1wd4] <cite>Miyanaga2004</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#Nogawa1999 pmid=10473402<br />
#Miyanaga2004 pmid=15292273<br />
#Miyanaga2006 pmid=16846393<br />
#Fujimoto2010 pmid=20739278<br />
#Ribeiro2010 pmid=20637315<br />
#Koseki2010 pmid=19756576<br />
<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM042]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_42&diff=9920Carbohydrate Binding Module Family 422014-05-16T07:42:22Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Shinya Fushinobu^^^<br />
* [[Responsible Curator]]: ^^^Shinya Fushinobu^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM42.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
This module was originally identified as a non-catalytic xylan-binding domain in [[GH54]] &alpha;-L-arabinofuranosidase from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=51453 ''Trichoderma reesei''] PC-3-7 <cite>Nogawa1999</cite>. In 2004, it was found to be a CBM specific for an L-arabinofuranosyl group because L-arabinofuranose molecules were bound to a non-catalytic domain of [[GH54]] &alpha;-L-arabinofuranosidase B from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=40384 ''Aspergillus kawachii''] (AkAbfB) <cite>Miyanaga2004</cite>. CBM42 members have multivalent (usually divalent or trivalent) binding ability to non-reducing end L-arabinofuranosyl residues, which are present in plant polysaccharides (hemicelluloses) such as arabinoxylan, arabinan, and arabinogalactan. Most of CBM42s are associated with &alpha;-L-arabinofuranosidases from fungi ([[GH54]]) or bacteria ([[GH43]]). <br />
<br />
== Structural Features ==<br />
[[Image:CBM42.png|'''Figure 1:''' CBM42 of &alpha;-L-arabinofuranosidase B from ''A. kawachii'' in complex with &alpha;-L-arabinofuranosyl-&alpha;-1,2-xylobiose (2D44). The &alpha;-domain is non-functional. |frame|right]]<br />
<br />
CBM42s have a &beta;-trefoil fold that is similar to [[CBM13]] and R(ricin)-type lectins ('''Figure 1'''). The module has a sequential 3-fold internal repeat of approximately 45 amino acid residues comprising three subdomains. The three subdomains are denoted as &alpha;, &beta;, and &gamma;. Each subdomain contains a discrete ligand binding site, but one of the three subdomains sometimes loses its function due to mutations at critical residues for ligand binding.<br />
<br />
CBM42s are typical [[Carbohydrate-binding_modules#Types|Type C CBMs]] that bind termini of glycans with pocket-type binding sites for short oligosaccharides. The binding pockets are small but can accommodate the branched side chain L-arabinofuranosyl moiety attached to the xylan backbone of arabinoxylans <cite>Miyanaga2006</cite>.<br />
<br />
The binding sites are located at side pockets of the triangular structure of the &beta;-trefoil fold. Residues important for the binding to a non-reducing end L-arabinofuranosyl group are as follows: an aspartate forming hydrogen bonds to the O2 and O3 hydroxyls, a histidine forming a hydrogen bond to the O5 hydroxyl, and two aromatic residues (tyrosine, tryptophan, or phenylalanine) stacking to the furanose sugar ('''Figure 1'''). They are D425, H416, Y417 and Y456 in the &beta;-subdomain of AkAbfB and are conserved in functional CBM42 subdomains.<br />
<br />
Several crystal structures including complex structures with compounds containing an L-arabinofuranosyl group are available. For example, AkAbfB (&alpha;-subdomain is non-functional) ([{{PDBlink}}1wd3 1wd3] [{{PDBlink}}1wd4 1wd4]) <cite>Miyanaga2004</cite>, ([{{PDBlink}}2d43 2d43] [{{PDBlink}}2d44 2d44]) <cite>Miyanaga2006</cite>; Exo-1,5-&alpha;-L-arabinofuranosidase from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=33903 ''Sreptomyces avermitilis''] (all subdomains are functional) ([{{PDBlink}}3akf 3akf] [{{PDBlink}}3akg 3akg] [{{PDBlink}}3akh 3akh] [{{PDBlink}}3aki 3aki]) <cite>Fujimoto2010</cite>; CBM42A in Cthe_0015 from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1515 ''Clostridium thermocellum''] (&beta;-subdomain is non-functional) ([{{PDBlink}}3kmv 3kmv]) <cite>Ribeiro2010</cite>.<br />
<br />
== Functionalities == <br />
CBM42s are thought to target catalytic modules (usually &alpha;-L-arabinofuranosidases) to hemicelluloses that have L-arabinofuranosyl termini or branches. Mutations at the binding sites of CBM42 significantly reduced the catalytic activity toward natural polysaccharides in these enzymes, whereas the activity toward ''p''-nitrophenyl &alpha;-L-arabinofuranoside was not affected <cite>Miyanaga2006 Ribeiro2010</cite>. These modules are commonly associated with &alpha;-L-arabinofuranosidases or exo-arabinanases of [[GH2]], [[GH43]], [[GH54]], [[GH93]], or non-classified GHs <cite>Ribeiro2010</cite>. A survey using the [http://www.ahv.dk/index.php/bioinformatic/cazy-tools/gh-cbm GH-CBM tool] shows that CBM42s are also associated with [[GH16]] or [[GH30]]. As a typical exo-type (Type C) CBM, the CBM42 in AkAbfB shows relatively low binding affinities to L-arabinofuranose-containing oligosaccharides with <i>K</i><sub>a</sub> values of 1~5 &times;10<sup>3</sup> M<sup>-1</sup>. <cite>Miyanaga2006</cite>. In a novel application of CBM42 molecules, a CBM42 was fused to a feruloyl esterase to create a chimeric enzyme with enhanced thermostability and exhibited a four-fold higher activity on insoluble arabinoxylan <cite>Koseki2010</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
The L-arabinofuranose-binding function of CBM42 was first suggested by crystallography of &alpha;-L-arabinofuranosidase B from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=40384 ''Aspergillus kawachii''] (AkAbfB) <cite>Miyanaga2004</cite>.<br />
;First Structural Characterization<br />
The first structure of CBM42 was revealed in 2004 in the x-ray crystal structure of AkAbfB in complex with arabinose as a full-length structure with a catalytic [[GH54]] domain [{{PDBlink}}1wd4 1wd4] <cite>Miyanaga2004</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#Nogawa1999 pmid=10473402<br />
#Miyanaga2004 pmid=15292273<br />
#Miyanaga2006 pmid=16846393<br />
#Fujimoto2010 pmid=20739278<br />
#Ribeiro2010 pmid=20637315<br />
#Koseki2010 pmid=19756576<br />
<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM042]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_28&diff=9919Carbohydrate Binding Module Family 282014-05-16T07:33:22Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Shinya Fushinobu^^^<br />
* [[Responsible Curator]]: ^^^Shinya Fushinobu^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM28.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
This module was first classified in 2002 by a characterization study of the C-terminal module in [[GH5]] Cel5A from ''Bacillus'' sp. 1139 (''Bsp''CBM28) <cite>Boraston2002</cite>. All known CBM28s are so far derrived from bacterial origins, mostly attached to cellulosomal endoglucanases in tandem with [[CBM17]]. They bind non-crystalline (or amorphous) part of cellulose, cellooligosaccharides, or &beta;-1,3-1,4-glucans <cite>Boraston2002 Boraston2003</cite>.<br />
<br />
== Structural Features ==<br />
[[Image:CBM28-17-4.png|'''Figure 1:''' CBM28 ([{{PDBlink}}3aci 3aci]) <cite>Tsukimoto2010</cite> in comparison with CBM17 ([{{PDBlink}}1j84 1j84]) <cite>Notenboom2011</cite> and CBM4 ([{{PDBlink}}1gu3 1gu3]) <cite>Boraston2002-2</cite>. Sugars of cellooligosaccharides (cellopentaose or cellotetraose) are designated as A-E from the non-reducing end to the reducing end. Ca<sup>2+</sup> ions in CBM28 and CBM17 are shown as green spheres in the ribbon representations (upper). Important residues in the cleft are colored yellow (aromatic), red (acidic), blue (basic), and green (neutral) on the molecular surfaces (lower). |frame|right]]<br />
<br />
CBM28s have a &beta;-sandwich fold (approximately 200 amino acids) that is similar to [[CBM17]] and [[CBM4]] ('''Figure 1'''). The module has a straight cleft that binds a cellulose glycan chain at the concave face of the &beta;-sandwich fold. A Ca<sup>2+</sup> ion is bound on the back side of molecule. The Ca<sup>2+</sup> ion is not involved in ligand binding but appears to play a structural stabilization role. These modules are typical endo-type [[Carbohydrate-binding_modules#Types|Type B CBMs]] that accommodate a single glycan chain in an open cleft.<br />
<br />
'''Figure 1''' shows the cellopentaose complex structure ([{{PDBlink}}3aci 3aci]) of CBM28 in [[GH5]] Cel5A from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1499 ''Clostridium josui''] (''Cj''CBM28). The long binding cleft runs at the center of the molecule. Therefore, the binding pocket location of CBM28 is on the concave face (side) of the &beta;-sandwich fold, not within the variable loop region ([[Carbohydrate-binding_modules#Fold|CBM Fold]]). The shallow cleft of CBM28 binds one side of the cellooligosaccharides (face-on) in contrast with the case of [[CBM4]] (side-on). There are at at least five subsites (A-E from the non-reducing end to the reducing end) in ''Cj''CBM28. Interestingly, the direction of the cellooligosaccharides bound to CBM28 is opposite to those in [[CBM17]] and [[CBM4]]. Subsites B, C, and E form stacking interactions with aromatic residues (W78, W129, and F128 in ''Cj''CBM28). The flanking hydroxyl groups are extensively recognized by direct or water-mediated hydrogen bonds. Therefore, CBM28 has a relatively wide cleft.<br />
<br />
<br />
== Functionalities == <br />
CBM28s are thought to target catalytic modules (endoglucanases) to non-crystalline region of cellulose. Deletion mutants of CBM28 in Cel5A from ''Bacillus'' sp. 1139 showed significantly decreased amounts of the soluble products from amorphous cellulose <cite>Boraston2003</cite>. They are exclusively associated with [[GH5]] endo-&beta;-1,4-glucanases and a survey using the [http://www.ahv.dk/index.php/bioinformatic/cazy-tools/gh-cbm GH-CBM tool] shows that CBM28s are not associated with other GH family domains. As a typical endo-type (Type B) CBM, CBM28s show the <i>K</i><sub>a</sub> values of 0.7-5.2 &times;10<sup>4</sup> M<sup>-1</sup> for the binding of cellooligosaccharides (cellotetraose to cellohexaose), and it is enthalpically driven <cite>Boraston2002 Araki2009</cite>. ''Bsp''CBM28 binds amorphous (regenerated) cellulose with high-affinity (<i>K</i><sub>a</sub> = 9.9 &times;10<sup>5</sup> M<sup>-1</sup>) and low-affinity (<i>K</i><sub>a</sub> = 2.1 &times;10<sup>4</sup> M<sup>-1</sup>) cites <cite>Boraston2003</cite>. A novel application of CBM28 molecules was recently published where ''Bsp''CBM28 was used as a marker to identify amorphous regions in cellulose in photoactivated localization microscopy (PALM) studies <cite>Fox2013</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
The first identified member is the C-terminal module in Cel5A from ''Bacillus'' sp. 1139 (''Bsp''CBM28) <cite>Boraston2002</cite><br />
<br />
;First Structural Characterization<br />
Partial assignment of the NMR data of a CBM28 in Cel5I from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1521 ''Clostridium cellulolyticum''] was reported in 2002 <cite>Mosbah2002</cite> but its three-dimensional structure is not reported yet. The first crystal structure was reported in 2004 for ''Bsp''CBM28 in apo form ([{{PDBlink}}1uww 1uww]) <cite>Jamal2004</cite>. The first ligand complex structures were reported in 2010 for CBM28 in Cel5A from [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=1499 ''C. josui''] (''Cj''CBM28) ([{{PDBlink}}3acf 3acf] [{{PDBlink}}3acg 3acg] [{{PDBlink}}3ach 3ach] [{{PDBlink}}3aci 3aci]) <cite>Tsukimoto2010</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#Boraston2002 pmid=11743880<br />
#Boraston2003 pmid=12427734<br />
#Tsukimoto2010 pmid=20159017<br />
#Notenboom2011 pmid=11733998<br />
#Boraston2002-2 pmid=12079353<br />
#Araki2009 pmid=19420681<br />
<br />
#Fox2013 pmid=23563526<br />
#Mosbah2002 pmid=12153043<br />
#Jamal2004 pmid=15136030<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM028]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_6&diff=9849Carbohydrate Binding Module Family 62014-01-20T11:06:42Z<p>Alicia Lammerts van Bueren: /* Ligand specificities */</p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Mirjam Czjzek^^^<br />
* [[Responsible Curator]]: ^^^Mirjam Czjzek^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM6.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
The ligand specificity of the first characterized CBM6, originating from a multimodular xylanase from ''Clostridium thermocellum'', was determined to be xylan <cite>Fernandes1999</cite>, although the results showed that this CBM6 was also able to bind to avicel and acid-swollen cellulose. This was also the first CBM6 for which a 3D structure was determined <cite>Czjzek2001</cite>, and multiple sequence alignments, analyzed in the light of the first 3D structure, already gave clear indications that large diversity in specificity was to be expected among CBM6 modules <cite>Czjzek2001</cite>. The first ligand-bound complex of a xylanase CBM6 (CsCBM6-3) from ''Clostridium stercorarium'' was crystallized by Boraston et al. <cite>Boraston2003</cite>. Remarkably, the characterization and 3D structure of a CBM6 from ''Cellvibrio mixtus'' revealed two distinct binding sites that displayed differential binding specificities <cite>Henshaw2004;Pires2004</cite>. CBM6 modules are in general attached to bacterial or archeal polysaccharide degrading enzymes and can be found attached to xylanases, cellulases, agarases, laminarinases, etc <cite>Michel2009</cite>. Interestingly, modules assigned to the CBM6 family have also been found associated to fungal enzymes and to the α-subunit of the coagulation factor G in horseshoe crabs (see [http://www.cazy.org/CBM6_eukaryota.html the occurance of CBM6 in eukaryotes]). In the latter case, the β-1,3-glucan binding of the C-terminal tandem CBM6s has been demonstrated <cite>Takaki2002</cite>. These CBM6s have characterized binding specificities for linear and branched/decorated xylan, β-1,4-glucan (or cellulose), mixed-linked β-1,3-1,4-glucan (or lichenan), agarose, β-1,3-glucan (or laminarin) or chitin. Based on phylogenetic analyses of all reported CBM6 sequences in 2009 (a total of 167), four subfamilies have been defined that coincide with classes of substrate binding specificity as follows : subfamily 6a, hemicellulose; subfamily 6b, xylan; subfamily 6c, β-glucans with a variety of linkages; and subfamily 6d, agarose <cite>Abbott2009</cite>.<br />
<br />
== Structural Features ==<br />
Like the majority of CBMs, CBM6s display the typical β-sandwich fold predominantly consisting of five antiparallel β-strands on one face and four anti-parallel β-strands on the other face, connected by loops with variable lengths. Within the hierarchical CATH classification the modules belong to the jelly-roll superfamily [http://www.cathdb.info/version/3.5/superfamily/2.60.120.260 2.60.120.260] called "galactose-binding domain-like" that contains 515 unique domains. <br />
The first identified ligand binding site was not located at a shallow cleft on the concave surface of the β-sheets (binding site II, formerly called cleft B in CBM6) as was typically observed in CBMs. Alternatively, a binding site was found located at the apex, within the connecting loops of the two β-sheets (binding site I, formerly cleft A in CBM6) ([{{PDBlink}}1gmm PDB 1gmm]). Due to the existence of the dual binding sites in CBM6s, both [[Carbohydrate-binding_modules|Type B and C]] binding properties have been observed for individual CBM6s. Interestingly, some CBM6s display binding affinities for both binding sites ([{{PDBlink}}1uyy PDB 1uyy]), either with distinct specificities for each site ([{{PDBlink}}1uy0 PDB 1uy0] and [{{PDBlink}}1uyz PDB 1uyz]) or synergistic binding involving both sites at the same time <cite>Pires2004</cite>, while binding properties of other CBM6s make use of only one binding site, which is in general site I at the apex (i.e. [{{PDBlink}}1uxx PDB 1uxx];[{{PDBlink}}1nae PDB 1nae];[{{PDBlink}}1w9w PDB 1w9w]). The apex site I is made up of two important, highly conserved aromatic residues (mostly W and Y) that "sandwich" a sugar monomer <cite>Czjzek2001;Abbott2009</cite>. These conserved residues are neighboured by a much more variable loop (defined as zone E in Abbott et al. <cite>Abbott2009</cite>) that make up the diversity in binding specificity. Consistently, a variable number of sugar-binding subsites have been observed for site I, ranging from one (end binder) up to five binding subsites. The precise structural and energetic contributions of four of the binding subsites have been dissected, for the first time, in detail by combining crystallography and isothermal titration calorimetry (ITC) in the case of the ''Clostridium stercorarium ''CsCBM6-1 <cite>Lammerts2004</cite>. To date, only one CBM6 has been structurally and biochemically characterized that makes use of binding site II, which is the CBM6 from ''Cellvibrio mixtus'' <cite>Henshaw2004;Pires2004</cite> ([{{PDBlink}}1uxz PDB 1uxz]). An updated list of all available three-dimensional structures is accessible at the [http://www.cazy.org/CBM6_structure.html Cazy CBM6 structures page].<br />
<br />
== Functionalities == <br />
The predominant functional role to date described for CBM6 modules is carbohydrate binding and targeting. It has been shown that this type of module synergistically enhances the activity of the adjacent catalytic domain on insoluble substrates. <br />
The most common associated modules are enzymes such as xylanases, lichenases, β-agarases, laminarinases, deacetylases; other modules that have been found associated to CBM6 are dockerins and in eukaryotic organisms coagulation factors.<br />
The CBM6 from ''Clostridium thermocellum'' has been used to label plant tissues <cite>McCartney2004</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
:The xylose binding CBM6 from a multi-modular xylanase/actetyl-esterase from ''Clostridium thermocellum'' (CtCBM6) was the first to be identified and biochemically characterized. To a lesser extent the module was also able to bind to avicel and acid-swollen cellulose <cite>Fernandes1999</cite>.<br />
;First Structural Characterization<br />
:The same xylose binding CBM6 from ''Clostridium thermocellum'' ([{{PDBlink}}1gmm PDB 1gmm]) was also the first structurally characterized CBM6. The 3D structure revealed that the location of the ligand-binding site of carbohydrate-binding modules that have evolved from a common sequence was not conserved <cite>Czjzek2001</cite>. The first CBM6 in complex with its ligand was determined for the CsCBM6-3 from ''Clostridium stercorarium'' ([{{PDBlink}}1o8p PDB 1o8p])<cite>Boraston2003</cite>.<br />
== References ==<br />
<biblio><br />
#Fernandes1999 pmid=10432306<br />
#Czjzek2001 pmid=11673472<br />
#Boraston2003 pmid=12634060 <br />
#Henshaw2004 pmid=15004011<br />
#Pires2004 pmid=15010454<br />
#Michel2009 pmid=19240276<br />
#Takaki2002 pmid=11830593<br />
#Abbott2009 pmid=19788273<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2004 pmid=14769335<br />
<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM006]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_6&diff=9848Carbohydrate Binding Module Family 62014-01-20T10:57:24Z<p>Alicia Lammerts van Bueren: /* Structural Features */</p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Mirjam Czjzek^^^<br />
* [[Responsible Curator]]: ^^^Mirjam Czjzek^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM6.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
The ligand specificity of the first characterized CBM6, originating from a multimodular xylanase from ''Clostridium thermocellum'', was determined to be xylan <cite>Fernandes1999</cite>, although the results showed that this CBM6 was also able to bind to avicel and acid-swollen cellulose. This was also the first CBM6 for which a 3D structure was determined <cite>Czjzek2001</cite>, and multiple sequence alignments, analyzed in the light of the first 3D structure, already gave clear indications that large diversity in specificity was to be expected among CBM6 modules <cite>Czjzek2001</cite>. The first ligand-bound complex of a xylanase CBM6 (CsCBM6-3) from ''Clostridium stercorarium'' was crystallized by Boraston et al. <cite>Boraston2003</cite>. Remarkably, the characterization and 3D structure of a CBM6 from ''Cellvibrio mixtus'' revealed two distinct binding sites that displayed differential binding specificities <cite>Henshaw2004;Pires2004</cite>. CBM6 modules are in general attached to bacterial or archeal polysaccharide degrading enzymes and can be found attached to xylanases, cellulases, agarases, laminarinases, etc <cite>Michel2009</cite>. Interestingly, modules assigned to the CBM6 family have also been found associated to fungal enzymes and to the α-subunit of the coagulation factor G in horseshoe crabs (see [http://www.cazy.org/CBM6_eukaryota.html the occurance of CBM6 in eukaryotes]). In the latter case, the β-1,3-glucan binding of the C-terminal tandem CBM6s has been demonstrated <cite>Takaki2002</cite>. Those CBM6s having characterized binding specificities cover : both linear and branched/decorated xylan, β-1,4-glucan (or cellulose), mixed-linked β-1,3-1,4-glucan (or lichenan), agarose, β-1,3-glucan (or laminarin) and chitin. Based on phylogenetic analyses of all reported CBM6 sequences in 2009 (a total of 167), four subfamilies have been defined that coincide with classes of substrate binding specificity as follows : subfamily 6a, hemicellulose; subfamily 6b, xylan; subfamily 6c, β-glucans with a variety of linkages; and subfamily 6d, agarose <cite>Abbott2009</cite>.<br />
<br />
== Structural Features ==<br />
Like the majority of CBMs, CBM6s display the typical β-sandwich fold predominantly consisting of five antiparallel β-strands on one face and four anti-parallel β-strands on the other face, connected by loops with variable lengths. Within the hierarchical CATH classification the modules belong to the jelly-roll superfamily [http://www.cathdb.info/version/3.5/superfamily/2.60.120.260 2.60.120.260] called "galactose-binding domain-like" that contains 515 unique domains. <br />
The first identified ligand binding site was not located at a shallow cleft on the concave surface of the β-sheets (binding site II, formerly called cleft B in CBM6) as was typically observed in CBMs. Alternatively, a binding site was found located at the apex, within the connecting loops of the two β-sheets (binding site I, formerly cleft A in CBM6) ([{{PDBlink}}1gmm PDB 1gmm]). Due to the existence of the dual binding sites in CBM6s, both [[Carbohydrate-binding_modules|Type B and C]] binding properties have been observed for individual CBM6s. Interestingly, some CBM6s display binding affinities for both binding sites ([{{PDBlink}}1uyy PDB 1uyy]), either with distinct specificities for each site ([{{PDBlink}}1uy0 PDB 1uy0] and [{{PDBlink}}1uyz PDB 1uyz]) or synergistic binding involving both sites at the same time <cite>Pires2004</cite>, while binding properties of other CBM6s make use of only one binding site, which is in general site I at the apex (i.e. [{{PDBlink}}1uxx PDB 1uxx];[{{PDBlink}}1nae PDB 1nae];[{{PDBlink}}1w9w PDB 1w9w]). The apex site I is made up of two important, highly conserved aromatic residues (mostly W and Y) that "sandwich" a sugar monomer <cite>Czjzek2001;Abbott2009</cite>. These conserved residues are neighboured by a much more variable loop (defined as zone E in Abbott et al. <cite>Abbott2009</cite>) that make up the diversity in binding specificity. Consistently, a variable number of sugar-binding subsites have been observed for site I, ranging from one (end binder) up to five binding subsites. The precise structural and energetic contributions of four of the binding subsites have been dissected, for the first time, in detail by combining crystallography and isothermal titration calorimetry (ITC) in the case of the ''Clostridium stercorarium ''CsCBM6-1 <cite>Lammerts2004</cite>. To date, only one CBM6 has been structurally and biochemically characterized that makes use of binding site II, which is the CBM6 from ''Cellvibrio mixtus'' <cite>Henshaw2004;Pires2004</cite> ([{{PDBlink}}1uxz PDB 1uxz]). An updated list of all available three-dimensional structures is accessible at the [http://www.cazy.org/CBM6_structure.html Cazy CBM6 structures page].<br />
<br />
== Functionalities == <br />
The predominant functional role to date described for CBM6 modules is carbohydrate binding and targeting. It has been shown that this type of module synergistically enhances the activity of the adjacent catalytic domain on insoluble substrates. <br />
The most common associated modules are enzymes such as xylanases, lichenases, β-agarases, laminarinases, deacetylases; other modules that have been found associated to CBM6 are dockerins and in eukaryotic organisms coagulation factors.<br />
The CBM6 from ''Clostridium thermocellum'' has been used to label plant tissues <cite>McCartney2004</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
:The xylose binding CBM6 from a multi-modular xylanase/actetyl-esterase from ''Clostridium thermocellum'' (CtCBM6) was the first to be identified and biochemically characterized. To a lesser extent the module was also able to bind to avicel and acid-swollen cellulose <cite>Fernandes1999</cite>.<br />
;First Structural Characterization<br />
:The same xylose binding CBM6 from ''Clostridium thermocellum'' ([{{PDBlink}}1gmm PDB 1gmm]) was also the first structurally characterized CBM6. The 3D structure revealed that the location of the ligand-binding site of carbohydrate-binding modules that have evolved from a common sequence was not conserved <cite>Czjzek2001</cite>. The first CBM6 in complex with its ligand was determined for the CsCBM6-3 from ''Clostridium stercorarium'' ([{{PDBlink}}1o8p PDB 1o8p])<cite>Boraston2003</cite>.<br />
== References ==<br />
<biblio><br />
#Fernandes1999 pmid=10432306<br />
#Czjzek2001 pmid=11673472<br />
#Boraston2003 pmid=12634060 <br />
#Henshaw2004 pmid=15004011<br />
#Pires2004 pmid=15010454<br />
#Michel2009 pmid=19240276<br />
#Takaki2002 pmid=11830593<br />
#Abbott2009 pmid=19788273<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2004 pmid=14769335<br />
<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM006]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9841Carbohydrate Binding Module Family 412014-01-17T09:17:55Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch (amylopectin), glycogen, amylose (linear alpha-1,4-linked glucose), and pullulan (alpha-1,6-linked maltotriose), and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains and may accommodate a linear alpha-1,6-linked glucose moiety. <br />
<br />
== Functionalities ==<br />
<br />
CBM41s are mainly associated with pullulanases and other starch/glycogen debranching enzymes of family [[GH13]]. CBM41s are shown to direct the enzyme onto alpha-1,4-glucan chains to situate the catalytic machinery towards alpha-1,6-branch points <cite>vanBueren2011</cite>. The majority of CBM41s are found in bacteria, including several pathogenic bacterial species such as ''Streptococcus'', ''Klebsiella'' and ''Bacillus'' <cite>vanBueren2004 vanBueren2007b</cite>. They are also found in eukaryotic red and green algae. An updated list of CBM41 family members can be found in the [http://www.cazy.org/CBM41_all.html CAZy Database]<br />
== Structural Features ==<br />
There are several [http://www.cazy.org/CBM41_structure.html X-ray crystal structures of CBM41 modules] of which the majority are in complex with carbohydrate ligand. All adopt a common beta-sandwich configuration with an immunoglobulin (Ig)-like fold. A concave-shaped binding groove is formed on the side of the protein molecule to accommodate the helical structure of alpha-1,4-linked maltooligosaccharides <cite>vanBueren2007a vanbueren2007b</cite>. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as [[Carbohydrate-binding_modules|Type B CBMs]]. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007a</cite>. <br />
<br />
The overall structural scaffold and mode of alpha-glucan recognition of CBM41 is similar to other starch-binding CBM families, which include CBM20, CBM21, CBM25, CBM26, CBM34, and CBM48. Although these different starch-binding module families have very little amino-acid sequence similarity to each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families <cite>Christiansen2009</cite>.<br />
<br />
Structural data are available for several full-length pullulanases and glycogen-debranching enzymes containing both catalytic modules and associated CBMs in complex with alpha-glucan substrates which has provided details on how modularity contributes to the overall function of these enzymes. For example, the x-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the first of two dual, tandemly arranged N-terminal CBM41 modules directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal [[GH13]] catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding which has so far has only been found to occur within CBM41-containing pullulanases. The second CBM41 of SpuA is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in 2006 in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== Novel Applications ==<br />
Fluorescently labelled ''Tm''CBM41 and ''Spn''DX modules have been used to label glycogen granules ''in situ'' in mouse lung tissue samples <cite>vanBueren2007b vanBueren2011</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
#vanBueren20072 pmid=17187076<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007a pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#Christiansen2009 pmid=19682075<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9840Carbohydrate Binding Module Family 412014-01-17T09:12:17Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch (amylopectin), glycogen, amylose (linear alpha-1,4-linked glucose), and pullulan (alpha-1,6-linked maltotriose), and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains and may accommodate a linear alpha-1,6-linked glucose moiety. <br />
<br />
== Functionalities ==<br />
<br />
CBM41 modules are mainly associated with pullulanases and other starch/glycogen debranching enzymes of family [[GH13]]. CBM41s are shown to direct the enzyme onto alpha-1,4-glucan chains to situate the catalytic machinery towards alpha-1,6-branch points <cite>vanBueren2011</cite>. The majority of CBM41s are found in bacteria, including several pathogenic bacterial species such as ''Streptococcus'', ''Klebsiella'' and ''Bacillus'' <cite>vanBueren2004 vanBueren2007b</cite>. They are also found in eukaryotic red and green algae.<br />
== Structural Features ==<br />
There are several [http://www.cazy.org/CBM41_structure.html X-ray crystal structures of CBM41 modules] of which the majority are in complex with carbohydrate ligand. All adopt a common beta-sandwich configuration with an immunoglobulin (Ig)-like fold. A concave-shaped binding groove is formed on the side of the protein molecule to accommodate the helical structure of alpha-1,4-linked maltooligosaccharides <cite>vanBueren2007a vanbueren2007b</cite>. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as [[Carbohydrate-binding_modules|Type B CBMs]]. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007a</cite>. <br />
<br />
The overall structural scaffold and mode of alpha-glucan recognition of CBM41 is similar to other starch-binding CBM families, which include CBM20, CBM21, CBM25, CBM26, CBM34, and CBM48. Although these different starch-binding module families have very little amino-acid sequence similarity to each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families <cite>Christiansen2009</cite>.<br />
<br />
Structural data are available for several full-length pullulanases and glycogen-debranching enzymes containing both catalytic modules and associated CBMs in complex with alpha-glucan substrates which has provided details on how modularity contributes to the overall function of these enzymes. For example, the x-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the first of two dual, tandemly arranged N-terminal CBM41 modules directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal [[GH13]] catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding which has so far has only been found to occur within CBM41-containing pullulanases. The second CBM41 of SpuA is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in 2006 in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== Novel Applications ==<br />
Fluorescently labelled ''Tm''CBM41 and ''Spn''DX modules have been used to label glycogen granules ''in situ'' in mouse lung tissue samples <cite>vanBueren2007b vanBueren2011</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
#vanBueren20072 pmid=17187076<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007a pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#Christiansen2009 pmid=19682075<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_6&diff=9839Carbohydrate Binding Module Family 62014-01-17T08:47:49Z<p>Alicia Lammerts van Bueren: cleaning up</p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Mirjam Czjzek^^^<br />
* [[Responsible Curator]]: ^^^Mirjam Czjzek^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM6.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
The ligand specificity of the first characterized CBM6, originating from a multimodular xylanase from ''Clostridium thermocellum'', was determined to be xylan <cite>Fernandes1999</cite>, although the results showed that this CBM6 was also able to bind to avicel and acid-swollen cellulose. This was also the first CBM6 for which a 3D structure was determined <cite>Czjzek2001</cite>, and multiple sequence alignments, analyzed in the light of the first 3D structure, already gave clear indications that large diversity in specificity was to be expected among CBM6 modules <cite>Czjzek2001</cite>. The first ligand-bound complex of a xylanase CBM6 (CsCBM6-3) from ''Clostridium stercorarium'' was crystallized by Boraston et al. <cite>Boraston2003</cite>. Remarkably, the characterization and 3D structure of a CBM6 from ''Cellvibrio mixtus'' revealed two distinct binding sites that displayed differential binding specificities <cite>Henshaw2004;Pires2004</cite>. CBM6 modules are in general attached to bacterial or archeal polysaccharide degrading enzymes and can be found attached to xylanases, cellulases, agarases, laminarinases, etc <cite>Michel2009</cite>. Interestingly, modules assigned to the CBM6 family have also been found associated to fungal enzymes and to the α-subunit of the coagulation factor G in horseshoe crabs (see [http://www.cazy.org/CBM6_eukaryota.html the occurance of CBM6 in eukaryotes]). In the latter case, the β-1,3-glucan binding of the C-terminal tandem CBM6s has been demonstrated <cite>Takaki2002</cite>. Those CBM6s having characterized binding specificities cover : both linear and branched/decorated xylan, β-1,4-glucan (or cellulose), mixed-linked β-1,3-1,4-glucan (or lichenan), agarose, β-1,3-glucan (or laminarin) and chitin. Based on phylogenetic analyses of all reported CBM6 sequences in 2009 (a total of 167), four subfamilies have been defined that coincide with classes of substrate binding specificity as follows : subfamily 6a, hemicellulose; subfamily 6b, xylan; subfamily 6c, β-glucans with a variety of linkages; and subfamily 6d, agarose <cite>Abbott2009</cite>.<br />
<br />
== Structural Features ==<br />
Likewise many other CBMs the CBM6 modules, roughly containing 120 amino acids, display the overall fold of a β-sandwich, predominantly consisting of five antiparallel β-strands on one face and four anti-parallel β-strands on the other face, connected by loops with variable lengths. Within the hierarchical CATH classification the modules belong to the jelly-roll superfamily [http://www.cathdb.info/version/3.5/superfamily/2.60.120.260 2.60.120.260] called "galactose-binding domain-like" that contains 515 unique domains. <br />
The first identified ligand binding site was not, as usual, located at a shallow cleft on the concave surface of the β-sheets (binding site II, formerly called cleft B in CBM6). Alternatively, a binding site was found located at the apex, within the connecting loops of the two β-sheets (binding site I, formerly cleft A in CBM6) ([{{PDBlink}}1gmm PDB 1gmm]). Due to the existence of the dual binding sites in CBM6s, both Type B and C binding properties have been observed for individual CBM6s. Interestingly, some CBM6s display binding affinities for both binding sites ([{{PDBlink}}1uyy PDB 1uyy]), either with distinct specificities for each site ([{{PDBlink}}1uy0 PDB 1uy0] and [{{PDBlink}}1uyz PDB 1uyz]) or synergistic binding involving both sites at the same time <cite>Pires2004</cite>, while binding properties of other CBM6s make use of only one binding site, which is in general site I at the apex (i.e. [{{PDBlink}}1uxx PDB 1uxx];[{{PDBlink}}1nae PDB 1nae];[{{PDBlink}}1w9w PDB 1w9w]). The apex site I is made up of two important, highly conserved aromatic residues (mostly W and Y) that "sandwich" a sugar monomer <cite>Czjzek2001;Abbott2009</cite>. These conserved residues are neighboured by a much more variable loop (defined as zone E in Abbott et al. <cite>Abbott2009</cite>) that make up the diversity in binding specificity. Consistently, a variable number of sugar-binding subsites have been observed for site I, ranging from one (end binder) up to five binding subsites. The precise structural and energetic contributions of four of the binding subsites have been dissected, for the first time, in detail by combining crystallography and isothermal titration calorimetry (ITC) in the case of the ''Clostridium stercorarium ''CsCBM6-1 <cite>Lammerts2004</cite>. To date, only one CBM6 has been structurally and biochemically characterized that makes use of binding site II, which is the CBM6 from ''Cellvibrio mixtus'' <cite>Henshaw2004;Pires2004</cite> ([{{PDBlink}}1uxz PDB 1uxz]). An updated list of all available three-dimensional structures is accessible at the [http://www.cazy.org/CBM6_structure.html Cazy CBM6 structures page].<br />
<br />
== Functionalities == <br />
The predominant functional role to date described for CBM6 modules is carbohydrate binding and targeting. It has been shown that this type of module synergistically enhances the activity of the adjacent catalytic domain on insoluble substrates. <br />
The most common associated modules are enzymes such as xylanases, lichenases, β-agarases, laminarinases, deacetylases; other modules that have been found associated to CBM6 are dockerins and in eukaryotic organisms coagulation factors.<br />
The CBM6 from ''Clostridium thermocellum'' has been used to label plant tissues <cite>McCartney2004</cite>.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
:The xylose binding CBM6 from a multi-modular xylanase/actetyl-esterase from ''Clostridium thermocellum'' (CtCBM6) was the first to be identified and biochemically characterized. To a lesser extent the module was also able to bind to avicel and acid-swollen cellulose <cite>Fernandes1999</cite>.<br />
;First Structural Characterization<br />
:The same xylose binding CBM6 from ''Clostridium thermocellum'' ([{{PDBlink}}1gmm PDB 1gmm]) was also the first structurally characterized CBM6. The 3D structure revealed that the location of the ligand-binding site of carbohydrate-binding modules that have evolved from a common sequence was not conserved <cite>Czjzek2001</cite>. The first CBM6 in complex with its ligand was determined for the CsCBM6-3 from ''Clostridium stercorarium'' ([{{PDBlink}}1o8p PDB 1o8p])<cite>Boraston2003</cite>.<br />
== References ==<br />
<biblio><br />
#Fernandes1999 pmid=10432306<br />
#Czjzek2001 pmid=11673472<br />
#Boraston2003 pmid=12634060 <br />
#Henshaw2004 pmid=15004011<br />
#Pires2004 pmid=15010454<br />
#Michel2009 pmid=19240276<br />
#Takaki2002 pmid=11830593<br />
#Abbott2009 pmid=19788273<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2004 pmid=14769335<br />
<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM006]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9808Carbohydrate Binding Module Family 412014-01-08T12:14:05Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
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<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch (amylopectin), glycogen, amylose (linear alpha-1,4-linked glucose), and pullulan (alpha-1,6-linked maltotriose), and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains and may accommodate a linear alpha-1,6-linked glucose moiety. <br />
<br />
== Functionalities ==<br />
<br />
CBM41 modules are associated with alpha-glucan debranching enzymes in family [[GH13]], including pullulanases (EC 3.2.1.41, [[GH13]] subfamily 14) and starch/glycogen debranching enzymes ([[GH13]] subfamily 12). They function in directing the enzyme onto alpha-1,4-glucan chains and situating the catalytic machinery towards alpha-1,6-branch points <cite>vanBueren2011</cite>. The most interesting feature of CBM41 modules is they are primarily associated with pullulanase-like enzymes originating from pathogenic bacteria, including pathogenic ''Streptococcus'', ''Klebsiella'' and ''Bacillus'' species <cite>vanBueren2004 vanBueren20072</cite>.<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. All adopt a common beta-sandwich configuration with an immunoglobulin (Ig)-like fold. A concave-shaped binding groove is formed on the side of the protein molecule to accommodate the helical structure of alpha-1,4-linked maltooligosaccharides. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as Type B CBMs. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007</cite>. <br />
<br />
The overall structural scaffold and mode of alpha-glucan recognition of CBM41 is similar to other starch-binding CBM families, which include CBM20, CBM21, CBM25, CBM26, CBM34, and CBM48. Although these different starch-binding module families have very little amino-acid sequence similarity to each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families <cite>Christiansen2009</cite>.<br />
<br />
Structural data are available for several full-length pullulanases and glycogen-debranching enzymes containing both catalytic modules and associated CBMs in complex with alpha-glucan substrates which has provided details on how modularity contributes to the overall function of these enzymes. For example, the x-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the first of two dual, tandemly arranged N-terminal CBM41 modules directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal [[GH13]] catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding which has so far has only been found to occur within CBM41-containing pullulanases. The second CBM41 of SpuA is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in 2006 in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== Novel Applications ==<br />
Fluorescently labelled ''Tm''CBM41 and ''Spn''DX modules have been used to label glycogen granules ''in situ'' in mouse lung tissue samples <cite>vanBueren20072 vanBueren2011</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
#vanBueren20072 pmid=17187076<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#Christiansen2009 pmid=19682075<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9433CAZypedia:Assigned pages2013-10-30T16:26:32Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Claire Dumon^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 11]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 22]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 30]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 50]]<br />
| ^^^Takayuki Ohnuma^^^<br />
| ^^^Takayuki Ohnuma^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| ^^^Nicole Koropatkin^^^<br />
| ^^^Nicole Koropatkin^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Cedric Montanier^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Cedric Montanier^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9432CAZypedia:Assigned pages2013-10-30T16:24:42Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| Claire Dumon<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 11]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 22]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 30]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 50]]<br />
| ^^^Takayuki Ohnuma^^^<br />
| ^^^Takayuki Ohnuma^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| Nicole Koropatkin<br />
| Nicole Koropatkin<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9420CAZypedia:Assigned pages2013-10-30T09:33:09Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| Claire Dumon<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 11]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 22]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 30]]<br />
| Carlos Fontes<br />
|<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| Invited<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 50]]<br />
| ^^^Takayuki Ohnuma^^^<br />
| ^^^Takayuki Ohnuma^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| Nicole Koropatkin<br />
| Nicole Koropatkin<br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| Invited<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| Invited<br />
| <br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9417CAZypedia:Assigned pages2013-10-29T14:56:50Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| Claire Dumon<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 11]]<br />
| Carlos Fontes<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 22]]<br />
| Carlos Fontes<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 30]]<br />
| Carlos Fontes<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 50]]<br />
| ^^^Takayuki Ohnuma^^^<br />
| ^^^Takayuki Ohnuma^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| Nicole Koropatkin<br />
| Nicole Koropatkin<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
<br />
<br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9416CAZypedia:Assigned pages2013-10-29T10:04:51Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| Claire Dumon<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 11]]<br />
| Carlos Fontes<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 22]]<br />
| Carlos Fontes<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 30]]<br />
| Carlos Fontes<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| Nicole Koropatkin<br />
| Nicole Koropatkin<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
<br />
<br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9415CAZypedia:Assigned pages2013-10-29T10:03:47Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| Claire Dumon<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 11]]<br />
| ^^^Carlos Fontes^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 22]]<br />
| ^^^Carlos Fontes^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 30]]<br />
| ^^^Carlos Fontes^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| Nicole Koropatkin<br />
| Nicole Koropatkin<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
<br />
<br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9414CAZypedia:Assigned pages2013-10-29T09:59:53Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| Claire Dumon<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 37]]<br />
| ^^^Ed Bayer^^^<br />
| Raphael Lamed<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 42]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 47]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Al Boraston^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 48]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 49]]<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 51]]<br />
| ^^^Al Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 58]]<br />
| Nicole Koropatkin<br />
| Nicole Koropatkin<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 60]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 61]]<br />
| ^^^Al Boraston^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| Cedric Montanier<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 63]]<br />
| Daniel Cosgrove<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 65]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 66]]<br />
| ^^^Harry Gilbert^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
<br />
<br />
|-<br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9413CAZypedia:Assigned pages2013-10-29T09:44:20Z<p>Alicia Lammerts van Bueren: /* Carbohydrate Binding Module Families */</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 3]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Rafael Lamed^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Claire Dumon^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 20]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 21]]<br />
| ^^^Birte Svensson^^^<br>^^^Stephan Janecek^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 25]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 26]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 27]]<br />
| ^^^Alisdair Boraston^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 28]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 29]]<br />
| ^^^Harry Gilbert^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 35]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 50]]<br />
| ^^^Takayuki Ohnuma^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=CAZypedia:Assigned_pages&diff=9412CAZypedia:Assigned pages2013-10-29T09:32:14Z<p>Alicia Lammerts van Bueren: adding assigned pages for CBM families test</p>
<hr />
<div>'''This page is a working document from the [[Board of Curators]] that lists the [[Responsible Curator]]s and [[Author]]s for various ''CAZypedia'' pages.'''<br />
<br />
* If you see that a page is missing and you want to act as [[Responsible Curator]] to edit and actively maintain that page, please contact the [[Board of Curators]] using [[Special:Contact|this e-mail form]].<br />
<br />
* If you would like to contribute to an existing page either as an [[Author]] or by suggesting improvements, please contact the [[Responsible Curator]] for that page. You may use this [[Special:Contact|this e-mail form]] to contact a [[Responsible Curator]] (if you know the Curator, you may also e-mail them directly).<br />
<br />
<br />
__TOC__<br />
<br />
== [[Glycoside Hydrolase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser''). To reset the page to be sorted by GH family, click the <span id="projectPage" style="color:blue">'''project page'''</span> tab at the very top of the page.<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycoside Hydrolase Family 1]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 2]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-25 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 3]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br>^^^Brian Mark^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-20<br />
|-<br />
| [[Glycoside Hydrolase Family 4]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Vivian Yip^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-23 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 5]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 6]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Kathleen Piens^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 7]]<br />
| ^^^Jerry Stahlberg^^^<br />
| ^^^Jerry Stahlberg^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-29<br />
|-<br />
| [[Glycoside Hydrolase Family 8]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br>^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 9]]<br />
| ^^^David Wilson^^^<br />
| ^^^David Wilson^^^<br>^^^Breeanna Urbanowicz^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-08-24<br />
|-<br />
| [[Glycoside Hydrolase Family 10]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 11]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Steve Withers^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-05-21 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 12]]<br />
| ^^^Mats Sandgren^^^<br />
| ^^^Mats Sandgren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 13]]<br />
| ^^^Birte Svensson^^^<br />
| ^^^Stefan Janecek^^^<br>^^^Birte Svensson^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-02<br />
|-<br />
| [[Glycoside Hydrolase Family 14]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 15]]<br />
| ^^^Pedro Coutinho^^^<br />
| ^^^Pedro Coutinho^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-06 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 16]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Jens Eklof^^^<br>^^^Jan-Hendrik Hehemann^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 17]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Geoff Fincher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 18]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br>^^^Nathalie Juge^^^<br>^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-12<br />
|-<br />
| [[Glycoside Hydrolase Family 19]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Vincent Eijsink^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-04-16<br />
|-<br />
| [[Glycoside Hydrolase Family 20]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 21]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 22]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Dave Vocadlo^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 23]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-18<br />
|-<br />
| [[Glycoside Hydrolase Family 24]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 25]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Ed Taylor^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-25<br />
|-<br />
| [[Glycoside Hydrolase Family 26]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-06-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 27]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-07-12 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 28]]<br />
| ^^^Richard Pickersgill^^^<br />
| ^^^Richard Pickersgill^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16 (stamped 2010-05-18)<br />
|-<br />
| [[Glycoside Hydrolase Family 29]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Gerlind Sulzenbacher^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 30]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 31]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Ran Zhang^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-14 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 32]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 33]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 34]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 35]]<br />
| ^^^Anna Kulminskaya^^^<br />
| ^^^Anna Kulminskaya^^^<br>^^^Mirko Maksimainen^^^<br>^^^Juha Rouvinen^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-03-21<br />
|-<br />
| [[Glycoside Hydrolase Family 36]]<br />
| ^^^Harry Brumer^^^<br />
| ^^^Harry Brumer^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2007-06-10 (stamped 2009-10-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 37]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-08<br />
|-<br />
| [[Glycoside Hydrolase Family 38]]<br />
| ^^^David Rose^^^<br />
| ^^^David Rose^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-21 (stamped 2010-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 39]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Brian Rempel^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 40]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 41]]<br />
| ^^^Bernard Henrissat^^^<br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 42]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Marco Moracci^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-03 (stamped 2009-11-28)<br />
|-<br />
| [[Glycoside Hydrolase Family 43]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-11-08<br />
|-<br />
| [[Glycoside Hydrolase Family 44]]<br />
| ^^^Peter Reilly^^^<br />
| ^^^Peter Reilly^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-01-17<br />
|-<br />
| [[Glycoside Hydrolase Family 45]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Gideon Davies^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 46]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 47]]<br />
| ^^^Spencer Williams^^^<br />
| ^^^Rohan Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-01-16<br />
|-<br />
| [[Glycoside Hydrolase Family 48]]<br />
| ^^^Ed Bayer^^^<br />
| ^^^Bareket Dassa^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-16<br />
|-<br />
| [[Glycoside Hydrolase Family 49]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-18<br />
|-<br />
| [[Glycoside Hydrolase Family 50]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-06-30<br />
|-<br />
| [[Glycoside Hydrolase Family 51]]<br />
| ^^^Yuval Shoham^^^<br />
| ^^^Yuval Shoham^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-05-10<br />
|-<br />
| [[Glycoside Hydrolase Family 52]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 53]]<br />
| ^^^Leila Lo Leggio^^^<br />
| ^^^Leila Lo Leggio^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-10<br />
|-<br />
| [[Glycoside Hydrolase Family 54]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Shinya Fushinobu^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 55]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyohiko Igarashi^^^<br>^^^Takuya Ishida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-27 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 56]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 57]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Stefan Janecek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-15<br />
|-<br />
| [[Glycoside Hydrolase Family 58]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-19<br />
|-<br />
| [[Glycoside Hydrolase Family 59]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 60]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 61]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 62]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 63]]<br />
| ^^^Takashi Tonozuka^^^<br />
| ^^^Takashi Tonozuka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-04-28<br />
|-<br />
| [[Glycoside Hydrolase Family 64]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 65]]<br />
| ^^^Hiroyuki Nakai^^^<br />
| ^^^Hiroyuki Nakai^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-29<br />
|-<br />
| [[Glycoside Hydrolase Family 66]]<br />
| ^^^Zui Fujimoto^^^<br />
| ^^^Ryuichiro Suzuki^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-10-06<br />
|-<br />
| [[Glycoside Hydrolase Family 67]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-26 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 68]]<br />
| ^^^Wim Van den Ende^^^<br />
| ^^^Tirso Pons^^^<br>^^^Wim Van den Ende^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-19<br />
|-<br />
| [[Glycoside Hydrolase Family 69]]<br />
| ^^^Bernard Henrissat^^^ <br />
| <br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 70]]<br />
| ^^^Stefan Janecek^^^<br />
| ^^^Magali Remaud-Simeon^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-09-05<br />
|-<br />
| [[Glycoside Hydrolase Family 71]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 72]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Jean-Paul Latge^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 73]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Florence Vincent^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-10-28<br />
|-<br />
| [[Glycoside Hydrolase Family 74]]<br />
| ^^^Katsuro Yaoi^^^<br />
| ^^^Katsuro Yaoi^^^<br>^^^Takuya Ishida^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 75]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-06-22<br />
|-<br />
| [[Glycoside Hydrolase Family 76]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 77]]<br />
| ^^^Stefan Janecek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 78]]<br />
| ^^^Zui Fujimoto^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Glycoside Hydrolase Family 79]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Hitomi Ichinose^^^<br>^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator approved]]''<br />
| 2012-03-09<br />
|-<br />
| [[Glycoside Hydrolase Family 80]]<br />
| ^^^Ryszard Brzezinski^^^<br />
| ^^^Ryszard Brzezinski^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-07-15<br />
|-<br />
| [[Glycoside Hydrolase Family 81]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 82]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Gurvan Michel^^^<br>^^^Mirjam Czjzek^^^<br>^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-17<br />
|-<br />
| [[Glycoside Hydrolase Family 83]]<br />
| ^^^Steve Withers^^^<br />
| ^^^Tom Wennekes^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 84]]<br />
| ^^^Dave Vocadlo^^^<br />
| ^^^Ian Greig^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-02-24<br />
|-<br />
| [[Glycoside Hydrolase Family 85]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 86]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Mirjam Czjzek^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-11-19<br />
|-<br />
| [[Glycoside Hydrolase Family 87]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 88]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 89]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Ficko-Blean^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-06<br />
|-<br />
| [[Glycoside Hydrolase Family 90]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 91]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 92]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-01-04<br />
|-<br />
| [[Glycoside Hydrolase Family 93]]<br />
| ^^^Annabelle Varrot^^^<br />
| ^^^Annabelle Varrot^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-08-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 94]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Masafumi Hidaka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-30 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 95]]<br />
| ^^^Takane Katayama^^^<br />
| ^^^Takane Katayama^^^ <br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 96]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 97]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Tracey Gloster^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 98]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Fathima Shaikh^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-10-28 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 99]]<br />
| ^^^Gideon Davies^^^<br />
| ^^^Spencer Williams^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-01-11<br />
|-<br />
| [[Glycoside Hydrolase Family 100]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 101]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 102]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 103]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-20<br />
|-<br />
| [[Glycoside Hydrolase Family 104]]<br />
| ^^^Anthony Clarke^^^<br />
| ^^^Anthony Clarke^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-02-21<br />
|-<br />
| [[Glycoside Hydrolase Family 105]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 106]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 107]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 108]]<br />
| <br />
| <br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 109]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-05 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 110]]<br />
| ^^^Bernard Henrissat^^^<br />
| ^^^Bernard Henrissat^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-10 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 111]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 112]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Motomitsu Kitaoka^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2009-07-15 (stamped 2009-11-08)<br />
|-<br />
| [[Glycoside Hydrolase Family 113]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 114]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 115]]<br />
| ^^^Satoshi Kaneko^^^<br />
| ^^^Satoshi Kaneko^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-12<br />
|-<br />
| [[Glycoside Hydrolase Family 116]]<br />
| ^^^Marco Moracci^^^<br />
| ^^^Beatrice Cobucci-Ponzano^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-22<br />
|-<br />
| [[Glycoside Hydrolase Family 117]]<br />
| ^^^Mirjam Czjzek^^^<br />
| ^^^Etienne Rebuffet^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2011-05-09<br />
|-<br />
| [[Glycoside Hydrolase Family 118]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 119]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 120]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 121]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 122]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 123]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 124]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Harry Gilbert^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-04-27<br />
|-<br />
| [[Glycoside Hydrolase Family 125]]<br />
| ^^^Alisdair Boraston^^^<br />
| ^^^Alisdair Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-16<br />
|-<br />
| [[Glycoside Hydrolase Family 126]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 127]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Kiyotaka Fujita^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 128]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 129]]<br />
| ^^^Shinya Fushinobu^^^<br />
| ^^^Hisashi Ashida^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-11-12<br />
|-<br />
| [[Glycoside Hydrolase Family 130]]<br />
|<br />
|<br />
| ''[[:Category:Unassigned pages|Unassigned]]''<br />
|-<br />
| [[Glycoside Hydrolase Family 131]]<br />
| ^^^Jean-Guy Berrin^^^<br />
| ^^^Jean-Guy Berrin^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2012-10-25<br />
|}<br />
<br />
== [[:Category:Polysaccharide Lyase Families|Polysaccharide Lyase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Polysaccharide Lyase Family 2]]<br />
| ^^^Wade Abbott^^^<br />
| ^^^Wade Abbott^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-30<br />
|-<br />
| [[Polysaccharide Lyase Family 8]]<br />
| ^^^Michael Suits^^^<br />
| ^^^Michael Suits^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
== [[:Category:Auxiliary Activity Families|Auxiliary Activity Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Auxiliary Activity Family 9]]<br />
| ^^^Paul Harris^^^<br />
| ^^^Paul Harris^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-09-19<br />
|-<br />
| [[Auxiliary Activity Family 10]]<br />
| ^^^Vincent Eijsink^^^<br />
| ^^^Gustav Vaaje-Kolstad^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|}<br />
<br />
<br />
== [[:Category:Carbohydrate Binding Module Families|Carbohydrate Binding Module Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Carbohydrate Binding Module Family 1]]<br />
| ^^^Markus Linder^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 4]]<br />
| ^^^Harry Gilbert^^^<br />
| ^^^Claire Dumon^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 6]]<br />
| ^^^Mirjam Czjzek^^^<br />
| <br />
| ''[[:Category:Under construction|Under Construction]]''<br />
|<br />
|-<br />
| [[Carbohydrate Binding Module Family 32]]<br />
| ^^^Elizabeth Ficko-Blean^^^<br />
| ^^^Elizabeth Ficko-Blean^^^<br>^^^Al Boraston^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2013-05-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 33]]<br />
| ^^^Bernard Henrissat^^^<br />
|<br />
| ''[[:Category:Deleted families|Deleted family]]''<br />
| 2013-04-22<br />
|-<br />
| [[Carbohydrate Binding Module Family 41]]<br />
| ^^^Al Boraston^^^<br />
| ^^^Alicia Lammerts van Bueren^^^<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|-<br />
| [[Carbohydrate Binding Module Family 50]]<br />
| ^^^Takayuki Ohnuma^^^<br />
|<br />
| ''[[:Category:Under construction|Under Construction]]''<br />
| <br />
|}<br />
<br />
== [[:Category:Glycosyltransferase Families|Glycosyltransferase Families]] ==<br />
Each column is sortable by clicking on the icons in the header (''javascript must be turned on in your browser'').<br />
{| cellspacing="0" cellpadding="4" border="0" class="sortable"<br />
|-<br />
! '''Family'''<br />
! '''[[Responsible Curator]]'''<br />
! '''[[Author]](s)'''<br />
! '''Page status'''<br />
! '''Date [[:Category:Curator approved|Curator Approved]]'''<br />
|-<br />
| [[Glycosyltransferase Family 42]]<br />
| ^^^Warren Wakarchuk^^^<br />
| ^^^Warren Wakarchuk^^^<br />
| ''[[:Category:Curator approved|Curator Approved]]''<br />
| 2010-07-08<br />
|}<br />
<br />
<br />
== [[Lexicon]] ==<br />
<br />
^^^Steve Withers^^^ and ^^^Spencer Williams^^^ are responsible for the various pages in the [[Lexicon]].</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=9411Carbohydrate-binding modules2013-10-28T11:25:23Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center"|'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
(starch/glycogen, mutan)<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>Based on the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. CBM7 is a deleted entry and CBM33 is now reclassified as Auxiliary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however a search based on amino acid sequence similarities found that similar modules are appended to many uncharacterized glycoside hydrolases <cite>Shallus2008</cite>.<br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxiliary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite> Shallus2008 Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme. <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=9401Carbohydrate-binding modules2013-10-19T16:02:35Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center"|'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
(starch/glycogen, mutan)<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>Based on the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. CBM7 is a deleted entry and CBM33 is now reclassified as Auxiliary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however a search based on amino acid sequence similarities found that similar modules are appended to many uncharacterized glycoside hydrolases <cite>Shallus2008</cite>.<br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
=== CBM Nomenclature ===<br />
<br />
Examples<br />
<br />
TmCBM41 <br />
<br />
CsCBM6-1<br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxiliary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite> Shallus2008 Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme. <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=9400Carbohydrate-binding modules2013-10-19T14:31:25Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center"|'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
(starch/glycogen, mutan)<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>Based on the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. CBM7 is a deleted entry and CBM33 is now reclassified as Auxiliary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however a search based on amino acid sequence similarities found that similar modules are appended to many uncharacterized glycoside hydrolases <cite>Shallus2008</cite>.<br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
=== CBM Nomenclature ===<br />
<br />
Examples<br />
<br />
TmCBM41 <br />
<br />
CsCBM6-1<br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxiliary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite> Shallus2008 Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9399Carbohydrate Binding Module Family 412013-10-18T12:55:42Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch (amylopectin), glycogen, amylose (linear alpha-1,4-linked glucose), and pullulan (alpha-1,6-linked maltotriose), and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains and may accommodate a linear alpha-1,6-linked glucose moiety. <br />
<br />
== Functionalities ==<br />
<br />
CBM41 modules are associated with alpha-glucan debranching enzymes in family GH13, including pullulanases (EC 3.2.1.41, GH13 subfamily 14) and starch/glycogen debranching enzymes (GH13 subfamily 12). They function in directing the enzyme onto alpha-1,4-glucan chains and situating the catalytic machinery towards alpha-1,6-branch points <cite>vanBueren2011</cite>. The most interesting feature of CBM41 modules is they are primarily associated with pullulanase-like enzymes originating from pathogenic bacteria, including pathogenic ''Streptococcus'', ''Klebsiella'' and ''Bacillus'' species <cite>vanBueren2004 vanBueren20072</cite>.<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. All adopt a common beta-sandwich fold and form a concave-shaped binding groove on the side of the protein molecule to accommodate the helical structure formed by alpha-1,4-linked maltooligosaccharides. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as Type B CBMs. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007</cite>. <br />
<br />
The overall structural scaffold and mode of alpha-glucan recognition of CBM41 is similar to other starch-binding CBM families, which include CBM20, CBM21, CBM25, CBM26, CBM34, and CBM48. Although these different starch-binding module families have very little amino-acid sequence similarity to each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families <cite>Christiansen2009</cite>.<br />
<br />
Structural data are available for several full-length pullulanases and glycogen-debranching enzymes containing both catalytic modules and associated CBMs in complex with alpha-glucan substrates which has provided details on how modularity contributes to the overall function of these enzymes. For example, the x-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the first of two dual, tandemly arranged N-terminal CBM41 modules directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal GH13 catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding which has so far has only been found to occur within CBM41-containing pullulanases. The second CBM41 of SpuA is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in 2006 in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== Novel Applications ==<br />
Fluorescently labelled ''Tm''CBM41 and ''Spn''DX modules have been used to label glycogen granules ''in situ'' in mouse lung tissue samples <cite>vanBueren20072 vanBueren2011</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
#vanBueren20072 pmid=17187076<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#Christiansen2009 pmid=19682075<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9398Carbohydrate Binding Module Family 412013-10-18T12:16:44Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch, glycogen, amylose, amylopectin and pullulan, and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains and can accommodate a linear alpha-1,6-linked glucose moiety. <br />
<br />
== Functionalities ==<br />
<br />
CBM41 modules are associated with alpha-glucan debranching enzymes in family GH13, including pullulanases (EC 3.2.1.41, GH13 subfamily 14) and starch/glycogen debranching enzymes (GH13 subfamily 12). They function in directing the enzyme onto alpha-1,4-glucan chains and situating the catalytic machinery towards alpha-1,6-branch points <cite>vanBueren2011</cite>. The most interesting feature of these modules is they are primarily associated with pullulanase-like enzymes originating from pathogenic bacteria, including pathogenic ''Streptococcus'', ''Klebsiella'' and ''Bacillus'' species <cite>vanBueren2004 vanBueren20072</cite>. <br />
<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. All adopt a common beta-sandwich fold and form a concave-shaped binding groove on the side of the protein molecule to accommodate the helical structure formed by alpha-1,4-linked maltooligosaccharides. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as Type B CBMs. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007</cite>. <br />
<br />
The overall structural scaffold and mode of alpha-glucan recognition of CBM41 is similar to other starch-binding CBM families, which include CBM20, CBM21, CBM25, CBM26, CBM34, and CBM48. Although these different starch-binding module families have very little amino-acid sequence similarity to each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families <cite>Christiansen2009</cite>.<br />
<br />
Structural data are available for several full-length pullulanases and glycogen-debranching enzymes containing both catalytic modules and associated CBMs in complex with alpha-glucan substrates which has provided details on how modularity contributes to the overall function of these enzymes. For example, the x-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the first of two dual, tandemly arranged N-terminal CBM41 modules directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal GH13 catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding which has so far has only been found to occur within CBM41-containing pullulanases. The second CBM41 of SpuA is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in 2006 in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== Novel Applications ==<br />
Fluorescently labelled ''Tm''CBM41 and ''Spn''DX modules have been used to label glycogen granules ''in situ'' in mouse lung tissue samples <cite>vanBueren20072 vanBueren2011</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
#vanBueren20072 pmid=17187076<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#Christiansen2009 pmid=19682075<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9397Carbohydrate Binding Module Family 412013-10-18T09:29:58Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch, glycogen, amylose, amylopectin and pullulan, and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains but can also accommodate a linear alpha-1,6-linked glucose moiety.<br />
<br />
== Functionalities ==<br />
<br />
CBM41 modules are associated with alpha-glucan debranching enzymes in family GH13, including pullulanases (EC 3.2.1.41 GH13 subfamily 14) and starch/glycogen debranching enzymes (GH13 subfamily 12). They function in directing the enzyme onto alpha-1,4-glucan chains and direct the catalytic machinery to alpha-1,6-branch points. The most interesting feature of these modules is they are primarily associated with pullulanase-like enzymes originating from pathogenic bacteria, including pathogenic ''Streptococcus'', ''Klebsiella'' and ''Bacillus''species. <br />
<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. All adopt a common beta-sandwich fold and form a concave-shaped binding groove on the side of the protein molecule to accommodate the helical structure formed by alpha-1,4-linked maltooligosaccharides. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as Type B CBMs. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007</cite>. The mode of starch binding by CBM41 is similar to other starch-binding CBM families, which include CBM20, CBM21, CBM25, CBM26, CBM34, and CBM48. Although these different starch-binding module families do not share amino-acid sequence similarities with each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families.<br />
<br />
X-ray crystal structures are available for several full-length pullulanases and glycogen-debranching enzymes containing both catalytic modules and associated CBMs in complex with alpha-glucan substrates. Full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' with its dual tandemly arranged N-terminal CBM41 modules revealed that the most N-terminal CBM41 module directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal GH13 catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding and thus far has only been found within CBM41-containing pullulanases. The second CBM41 is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module. These full length structures provides a unique opportunity to see how modularity of glycoside hydrolases contributes to their overall function.<br />
<br />
<br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Fold:''' Structural fold (beta trefoil, beta sandwich, etc.)<br />
* '''Type:''' Include here Type A, B, or C and properties<br />
* '''Features of ligand binding:''' Describe CBM binding pocket location (Side or apex) important residues for binding (W, Y, F, subsites), interact with reducing end, non-reducing end, planar surface or within polysaccharide chains. Include examples pdb codes. Metal ion dependent. Etc.<br />
<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== Novel Applications ==<br />
* '''Novel Applications:''' Include here if CBM has been used to modify another enzyme, or if a CBM was used to label plant/mammalian tissues? Etc.<br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9396Carbohydrate Binding Module Family 412013-10-18T09:09:19Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch, glycogen, amylose, amylopectin and pullulan, and shorter alpha glucan oligosaccharides derived from these polysaccharides including maltose, maltotriose, longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. CBM41 modules are specific for alpha-1,4-linked glucose chains but can also accommodate a linear alpha-1,6-linked glucose moiety.<br />
<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. All adopt a common beta-sandwich fold and form a concave-shaped binding groove on the side of the protein molecule to accommodate the helical structure formed by alpha-1,4-linked maltooligosaccharides. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule, with a third tryptophan creating a platform for interacting with longer maltooligosaccharide chains. The binding groove is made up of 4 binding subsites that interact with up to 4 intra-chain alpha-1,4-linked glucose molecules, classifying them as Type B CBMs. The CBM41 module from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue in the fourth subsite, demonstrating that there is room for flexibility in the linkage that can be accommodated at this site <cite>vanBueren2007</cite>. The mode of starch binding by CBM41 is similar to other starch-binding CBM families, which include CBM20, 21, , 25, 26, 34, and 48. Although these different starch-binding module families do not share amino-acid sequence similarities with each other, that fact that they share almost identical modes of starch-binding suggests a common evolution towards maltooligosaccharide recognition by all starch-binding CBM families.<br />
<br />
There are X-ray crystal structures available for several full-length pullulanases and glycogen-debranching enzymes containing both their catalytic modules and associated CBMs in complex with substrate which has allowed us to understand how modularity of these enzymes contributes to their overall function. Full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' with its dual tandemly arranged N-terminal CBM41 modules revealed that the most N-terminal CBM41 module directly participates in binding alpha-1,6-linked glucose branch points within the active site of the C-terminal GH13 catalytic module <cite>vanBueren2011</cite>. This is the first demonstration that a CBM directly participates in substrate binding and thus far this feature has only been found within this class of enzyme. The second CBM41 is available to interact with an adjacent alpha-glucan chain, suggesting a possible disruptive role for these CBMs in loosening granular glycogen and increasing the substrate availability for the catalytic module.<br />
<br />
<br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Fold:''' Structural fold (beta trefoil, beta sandwich, etc.)<br />
* '''Type:''' Include here Type A, B, or C and properties<br />
* '''Features of ligand binding:''' Describe CBM binding pocket location (Side or apex) important residues for binding (W, Y, F, subsites), interact with reducing end, non-reducing end, planar surface or within polysaccharide chains. Include examples pdb codes. Metal ion dependent. Etc.<br />
<br />
== Functionalities == <br />
<br />
Unlike other starch-binding CBM families, CBM41 modules are solely associated with starch debranching enzymes in family GH13, including pullulanases (EC 3.2.1.41 GH13 subfamily 14) and starch/glycogen debranching enzymes (GH13 subfamily 12). The most interesting feature of these modules is they are primarily associated with pullulanase-like enzymes originating from pathogenic bacteria, including pathogenic ''Streptococcus'', ''Klebsiella'' and ''Bacillus''species. The role of CBM41 is to direct the enzyme onto alpha-1,4-glucan chains and direct the catalytic machinery to alpha-1,6-branch points.<br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Functional role of CBM:''' Describe common functional roles such as targeting, disruptive, anchoring, proximity/position on substrate.<br />
* '''Most Common Associated Modules:''' 1. Glycoside Hydrolase Activity; 2. Additional Associated Modules (other CBM, FNIII, cohesin, dockerins, expansins, etc.)<br />
* '''Novel Applications:''' Include here if CBM has been used to modify another enzyme, or if a CBM was used to label plant/mammalian tissues? Etc.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9380Carbohydrate Binding Module Family 412013-10-15T11:44:16Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch, glycogen, amylose, amylopectin and pullulan, and shorter alpha glucan oligosaccharides derrived from these ploysaccharides including maltose, maltotriose and longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. In larger polysaccharides CBM41 modules are specific for alpha-1,4-linked glucose chains but can also accommodate a linear alpha-1,6-linked glucose moiety. CBM41 modules are linked to alpha-glucan degrading enzymes from family GH13, exclusively with pullulanases (EC 3.2.1.41 GH13 subfamily 14) and starch/glycogen debranching enzymes (GH13 subfamily 12).<br />
<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. CBM41 modules adopt a common beta-sandwich fold with the binding groove for alpha-glucans located on the face of the beta-sandwich fold. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule. The binding site includes 4 subsites that interact with up to 4 intra-chain glucose molecules, classifying them as Type B CBMs <cite>Gilbert2013</cite>. The mode of starch binding is similar to other starch-binding CBM families, including CBM20, 21, 34, 48. The fourth subsite in CBM41 from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue, demonstrating that there is room for flexibility in the linkage that can be accommodated at the distal end of the binding pocket, making them distinct from other starch-binding module families <cite>vanBueren2007</cite>.<br />
<br />
The X-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the N-terminal CBM41 module directly participates in alpha-glucan substrate binding within the active sit of the of the adjoining GH13 catalytic module <cite>vanBueren2011</cite>. This is the first demonstration of a direct involvement of a CBM in substrate binding and thus far has only been found within this class of enzyme.<br />
<br />
<br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Fold:''' Structural fold (beta trefoil, beta sandwich, etc.)<br />
* '''Type:''' Include here Type A, B, or C and properties<br />
* '''Features of ligand binding:''' Describe CBM binding pocket location (Side or apex) important residues for binding (W, Y, F, subsites), interact with reducing end, non-reducing end, planar surface or within polysaccharide chains. Include examples pdb codes. Metal ion dependent. Etc.<br />
<br />
== Functionalities == <br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Functional role of CBM:''' Describe common functional roles such as targeting, disruptive, anchoring, proximity/position on substrate.<br />
* '''Most Common Associated Modules:''' 1. Glycoside Hydrolase Activity; 2. Additional Associated Modules (other CBM, FNIII, cohesin, dockerins, expansins, etc.)<br />
* '''Novel Applications:''' Include here if CBM has been used to modify another enzyme, or if a CBM was used to label plant/mammalian tissues? Etc.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X28 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X28 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9379Carbohydrate Binding Module Family 412013-10-15T11:33:38Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch, glycogen, amylose, amylopectin and pullulan, and shorter alpha glucan oligosaccharides derrived from these ploysaccharides including maltose, maltotriose and longer maltooligosaccharides up to DP7, glucosyl-maltotriose and glucosyl-maltotriosyl-maltotriose <cite>vanBueren2004</cite>. In larger polysaccharides CBM41 modules are specific for alpha-1,4-linked glucose chains but can also accommodate a linear alpha-1,6-linked glucose moiety. CBM41 modules are linked to alpha-glucan degrading enzymes from family GH13, exclusively with pullulanases (EC 3.2.1.41 GH13 subfamily 14) and starch/glycogen debranching enzymes (GH13 subfamily 12).<br />
<br />
== Structural Features ==<br />
To date there are 11 X-ray crystal structures of CBM41 modules of which seven are in complex with carbohydrate ligand. CBM41 modules adopt a common beta-sandwich fold with the binding groove for alpha-glucans located on the face of the beta-sandwich fold. Typically two solvent exposed tryptophan residues form hydrophobic stacking interactions with the primary glucose molecule. The binding site includes 4 subsites that interact with up to 4 intra-chain glucose molecules, classifying them as Type B CBMs <cite>Gilbert2013</cite>. The mode of starch binding is similar to other starch-binding CBM families, including CBM20, 21, 34, 48. The fourth subsite in CBM41 from ''Thermotoga maritima'' was shown to accommodate either an alpha-1,4 or alpha-1,6-linked glucose residue, demonstrating that there is room for flexibility in the linkage that can be accommodated at the distal end of the binding pocket, making them distinct from other starch-binding module families <cite>vanBueren2007</cite>.<br />
<br />
The X-ray crystal structure of full length glycogen-debranching enzyme SpuA from ''Streptococcus pneumoniae'' revealed that the N-terminal CBM41 module directly participates in alpha-glucan substrate binding within the active sit of the of the adjoining GH13 catalytic module <cite>vanBueren2011</cite>. This is the first demonstration of a direct involvement of a CBM in substrate binding and thus far has only been found within this class of enzyme.<br />
<br />
<br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Fold:''' Structural fold (beta trefoil, beta sandwich, etc.)<br />
* '''Type:''' Include here Type A, B, or C and properties<br />
* '''Features of ligand binding:''' Describe CBM binding pocket location (Side or apex) important residues for binding (W, Y, F, subsites), interact with reducing end, non-reducing end, planar surface or within polysaccharide chains. Include examples pdb codes. Metal ion dependent. Etc.<br />
<br />
== Functionalities == <br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Functional role of CBM:''' Describe common functional roles such as targeting, disruptive, anchoring, proximity/position on substrate.<br />
* '''Most Common Associated Modules:''' 1. Glycoside Hydrolase Activity; 2. Additional Associated Modules (other CBM, FNIII, cohesin, dockerins, expansins, etc.)<br />
* '''Novel Applications:''' Include here if CBM has been used to modify another enzyme, or if a CBM was used to label plant/mammalian tissues? Etc.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
Family 41 CBMs were previously known as X20 modules. They were first classified as a CBM in 2004 after demonstrating alpha-glucan binding by an N-terminal X20 module from Thermotoga maritima pullulanase PulA <cite>vanBueren2004</cite><br />
;First Structural Characterization<br />
The first structure of CBM41 was revealed in the x-ray crystal structure of full-length pullulanase from ''Klebsiella pneumoniae'' <cite>Mikami2006</cite>. <br />
<br />
== References ==<br />
<biblio><br />
#vanBueren2004 pmid=15581376<br />
<br />
#Gilbert2013 pmid=23769966<br />
#vanBueren2007 pmid=17095014<br />
#vanBueren2011 pmid=21565699<br />
#Mikami2006 pmid=16650854<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate_Binding_Module_Family_41&diff=9378Carbohydrate Binding Module Family 412013-10-15T08:59:11Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^<br />
----<br />
<br />
<!-- The data in the table below should be updated by the Author/Curator according to current information on the family --><br />
<div style="float:right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}CBM41.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Ligand specificities ==<br />
Modules from family CBM41 bind to alpha-glucans including starch, glycogen, amylose, amylopectin and pullulan. They are specific for alpha-1,4-linked glucose but can also accommodate alpha-1,6-linked glucose in pullulan. CBM41 modules are linked with alpha glucan degrading enzymes from GH13 with pullulanases (EC 3.2.1.41 GH13 subfamily 14) and glycogen debranching enzymes (GH13 subfamily 12).<br />
<br />
''Note: Here is an example of how to insert references in the text, together with the "biblio" section below:'' Please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed <cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
== Structural Features ==<br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Fold:''' Structural fold (beta trefoil, beta sandwich, etc.)<br />
* '''Type:''' Include here Type A, B, or C and properties<br />
* '''Features of ligand binding:''' Describe CBM binding pocket location (Side or apex) important residues for binding (W, Y, F, subsites), interact with reducing end, non-reducing end, planar surface or within polysaccharide chains. Include examples pdb codes. Metal ion dependent. Etc.<br />
<br />
== Functionalities == <br />
''Content in this section should include, in paragraph form, a description of:''<br />
* '''Functional role of CBM:''' Describe common functional roles such as targeting, disruptive, anchoring, proximity/position on substrate.<br />
* '''Most Common Associated Modules:''' 1. Glycoside Hydrolase Activity; 2. Additional Associated Modules (other CBM, FNIII, cohesin, dockerins, expansins, etc.)<br />
* '''Novel Applications:''' Include here if CBM has been used to modify another enzyme, or if a CBM was used to label plant/mammalian tissues? Etc.<br />
<br />
== Family Firsts ==<br />
;First Identified<br />
:Insert archetype here, possibly including ''very brief'' synopsis.<br />
;First Structural Characterization<br />
:Insert archetype here, possibly including ''very brief'' synopsis.<br />
<br />
== References ==<br />
<biblio><br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
</biblio><br />
<br />
[[Category:Carbohydrate Binding Module Families|CBM041]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=9377Carbohydrate-binding modules2013-10-15T08:37:05Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center"|'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
(starch/glycogen, mutan)<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>Based on the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. CBM7 is a deleted entry and CBM33 is now reclassified as Auxiliary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however a search based on amino acid sequence similarities found that similar modules are appended to many uncharacterized glycoside hydrolases <cite>Shallus2008</cite>.<br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxiliary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite> Shallus2008 Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8970Carbohydrate-binding modules2013-07-16T18:41:02Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center"|'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
(starch/glycogen, mutan)<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>Based on the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. CBM7 is a deleted entry and CBM33 is now reclassified as Auxillary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however a search based on amino acid sequence similarities found that similar modules are appended to many uncharacterized glycoside hydrolases <cite>Shallus2008</cite>.<br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite> Shallus2008 Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8969Carbohydrate-binding modules2013-07-16T12:33:00Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" float="right" |'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
starch/glycogen, mutan<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>CBM7 is a deleted entry and CBM33 is now reclassified as Auxillary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however the module was found appended to many as yet uncharacterized glycoside hydrolases <cite>Shallus2008</cite><br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite> Shallus2008 Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8968Carbohydrate-binding modules2013-07-16T12:28:37Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" float="right" |'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
starch/glycogen, mutan<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>CBM7 is a deleted entry and CBM33 is now reclassified as Auxillary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however the module was found appended to many as yet uncharacterized glycoside hydrolases <cite>Schallus2008</cite><br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. (Insert some examples here). <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8967Carbohydrate-binding modules2013-07-16T12:26:46Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular enzyme (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" float="right" |'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
starch/glycogen, mutan<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>CBM7 is a deleted entry and CBM33 is now reclassified as Auxillary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however the module was found appended to many as yet uncharacterized glycoside hydrolases <cite>Schallus2008</cite><br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM-Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Multivalency is the collective strength of several interactions with a given ligand. Because CBM-carbohydrate interactions are relatively weak, some carbohydrate-active enzymes, mainly glycoside hydrolases, have developed ways to increase their interaction with substrate via a multivalent effect. Individually, some CBMs may contain multiple binding sites to form a multivalent interaction with their target ligand, although this form of multivalency is quite rare with only a few examples (CBM6, CBM13, CBM20). More commonly, glycoside hydrolases may contain more than one CBM within its modular architecture, either arranged in tandem or at opposing N and C terminal ends of the protein sequence, or both. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. (Insert some examples here). A multivalent interaction enhances the overall affinity of an enzyme for its substrate but more importantly, tandem CBMs will cooperatively target the enzyme towards specific regions within a larger polysaccharide substrate based on the orientation and position of binding sites with respect to one another. <br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8966Carbohydrate-binding modules2013-07-16T11:52:38Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" float="right" |'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
starch/glycogen, mutan<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>b</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>CBM7 is a deleted entry and CBM33 is now reclassified as Auxillary Activities family [[AA10]]. <br/><sup>b</sup>only human lectin malectin has been characterized, however the module was found appended to many as yet uncharacterized glycoside hydrolases <cite>Schallus2008</cite><br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Many glycoside hydrolases will have more than one CBM within its modular architecture. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. Individually each CBM will have a relatively low affinity for its target ligand (K<sub>a</sub> mM<sup>-1</sup> - uM<sup>-1</sup> range) but together all of the CBMs present will create a multivalent effect, increasing the overall the avidity (the strength of multiple interactions) of the enzyme for its substrate.<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8965Carbohydrate-binding modules2013-07-16T11:44:43Z<p>Alicia Lammerts van Bueren: edit table - need help with spacing and page positioning</p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="width:550px;" align="left"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" float="right" |'''Table 1: List of Carbohydrates and Interacting CBM Families<sup>a,b</sup>'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant Cell Wall - Other'''<br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Alpha-glucans'''<br />
starch/glycogen, mutan<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57<sup>c</sup><br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br/>Fructans: CBM38, CBM66<br/>Yeast cell wall glucans: CBM54<br />
|-<br />
|-<br />
| colspan="2" |<sup>a</sup>CBM7 is a deleted entry.<br/><sup>b</sup>CBM33 is now recategorized as Auxillary Activities AA10. <br/><sup>c</sup>only human lectin malectin has been characterized, however the module was found appended to many as yet uncharacterized glycoside hydrolases <cite>Schallus2008</cite><br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Many glycoside hydrolases will have more than one CBM within its modular architecture. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. Individually each CBM will have a relatively low affinity for its target ligand (K<sub>a</sub> mM<sup>-1</sup> - uM<sup>-1</sup> range) but together all of the CBMs present will create a multivalent effect, increasing the overall the avidity (the strength of multiple interactions) of the enzyme for its substrate.<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8964Carbohydrate-binding modules2013-07-16T08:53:36Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
<div style="right"><br />
{| {{Prettytable}} <br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''Table 1: List of Carbohydrates and Interacting CBM Families'''<br />
|-<br />
|'''Cellulose''' <br />
|CBM1, CBM2, CBM3, CBM4, CBM6, CBM8, CBM9, CBM10, CBM16, CBM17, CBM28, CBM30, CBM37, CBM44, CBM46, CBM49, CBM59, CBM63, CBM64<br />
|-<br />
|'''Chitin'''<br />
|CBM1, CBM2, CBM3, CBM5, CBM12, CBM14, CBM18, CBM19, CBM37, CBM50, CBM54, CBM55<br />
|-<br />
|'''Xylan'''<br />
|CBM2, CBM4, CBM6, CBM9, CBM13, CBM15, CBM22, CBM31, CBM35, CBM36, CBM37, CBM44, CBM54, CBM59, CBM60<br />
|-<br />
|'''Plant cell wall - other <br />
(eg: beta-glucans, porphyrans, pectins, mannans, gluco- and galacturonans)'''<br />
|CBM4, CBM6, CBM11, CBM13, CBM16, CBM22, CBM23, CBM27, CBM28, CBM29, [[CBM32]], CBM35, CBM39, CBM42, CBM43, CBM52, CBM56, CBM59, CBM61, CBM62, CBM65, CBM67 <br />
|-<br />
|'''Alpha-glucans'''<br />
|CBM20, CBM21, CBM24, CBM25, CBM26, CBM34, CBM41, CBM45, CBM48, CBM53, CBM58<br />
|-<br />
|'''Mammalian Glycans'''<br />
|[[CBM32]], CBM40, CBM47, CBM51, CBM57*<br />
|-<br />
|'''Other'''<br />
|Bacterial cell wall sugars: CBM35, CBM39, CBM50<br />
Fructans: CBM38, CBM66<br />
<br />
Yeast cell wall glucans: CBM54<br />
|-<br />
<br />
|-<br />
| colspan="2" | *only human lectin malectin has been characterized, however the module was found appended to many as yet uncharacterized glycoside hydrolases <cite>Schallus2008</cite><br />
<br />
CBM7 is a deleted entry<br />
<br />
CBM33 is now recategorized as Auxillary Activities AA10<br />
|}<br />
</div><br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (see multiple entries in Table 1).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Many glycoside hydrolases will have more than one CBM within its modular architecture. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. Individually each CBM will have a relatively low affinity for its target ligand (K<sub>a</sub> mM<sup>-1</sup> - uM<sup>-1</sup> range) but together all of the CBMs present will create a multivalent effect, increasing the overall the avidity (the strength of multiple interactions) of the enzyme for its substrate.<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid=2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
#Shallus2008 pmid=18524852<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8927Carbohydrate-binding modules2013-07-15T14:07:19Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. [[CBM33]] was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Many glycoside hydrolases will have more than one CBM within its modular architecture. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. Individually each CBM will have a relatively low affinity for its target ligand (K<sub>a</sub> mM<sup>-1</sup> - uM<sup>-1</sup> range) but together all of the CBMs present will create a multivalent effect, increasing the overall the avidity (the strength of multiple interactions) of the enzyme for its substrate.<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is a list of several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid= Normal 0 false false false EN-GB JA X-NONE 2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
Normal 0 false false false EN-GB JA X-NONE <br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8926Carbohydrate-binding modules2013-07-15T14:03:08Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as an amino acid sequence within a larger encoded protein sequence and fold into a structurally discreet module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not generally undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket or cleft. However, multimodular enzymes as a whole may be quite flexible and undergo significant conformational changes when binding substrate. Flexible Ser-Thr-Pro sequences, which are often O-glycosylated, link adjacent modules and can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity. It rapidly became evident that CBDs were not only appended to cellulases but were also found in a range of other plant cell wall degrading enzymes <cite>Kellett1990 Ferriera1990 Ferriera1993</cite>.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD (for example see <cite>Svensson1989</cite>). The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>). Since this time, CBMs have been found appended to enzymes that interact with almost all characterized carbohydrate sources found on Earth (Table 1).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the planar polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). Type B are the most abundant form of CBMs reported to date. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to generally accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). There are some examples in CBM6, CBM36 and CBM60 that contain only two subsites. <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47, CBM66, CBM67). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 10]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. Family CBM37 exhibit broad binding specificity for xylan, chitin and cellulose (ref). Family CBM41 appended to a [[GH13]] pullulanase can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Many glycoside hydrolases will have more than one CBM within its modular architecture. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. Individually each CBM will have a relatively low affinity for its target ligand (K<sub>a</sub> mM<sup>-1</sup> - uM<sup>-1</sup> range) but together all of the CBMs present will create a multivalent effect, increasing the overall the avidity (the strength of multiple interactions) of the enzyme for its substrate.<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
#Kellett1990 pmid=2125205<br />
#Ferriera1990 pmid= Normal 0 false false false EN-GB JA X-NONE 2115772<br />
#Ferriera1993 pmid=8373350<br />
#Svensson1989 pmid=2481445<br />
Normal 0 false false false EN-GB JA X-NONE <br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8925Carbohydrate-binding modules2013-07-15T12:44:50Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. A family CBM41 can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
Many glycoside hydrolases will have more than one CBM within its modular architecture. These CBMs may target the same carbohydrate ligand, different regions within the same ligand, or different ligands within a larger polysaccharide amalgam. Individually each CBM will have a relatively low affinity for its target ligand (K<sub>a</sub> mM<sup>-1</sup> - uM<sup>-1</sup> range) but together all of the CBMs present will create a multivalent effect, increasing the overall the avidity (the strength of multiple interactions) of the enzyme for its substrate.<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8924Carbohydrate-binding modules2013-07-15T09:32:13Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. A family CBM41 can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility in carbohydrate recognition by CBMs contributes to the [[#Functional Roles of CBMs|targeting]] efficiency of carbohydrate-active enzymes in environments where there is diverse range of polysaccharides present (such as the plant cell wall or mammalian tissues).<br />
<br />
=== CBMs and Multivalency ===<br />
<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8923Carbohydrate-binding modules2013-07-15T09:16:01Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin <cite>Boraston20032 Lammerts2005</cite>. A family CBM41 can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility of CBM ligand recognition due to ligand promiscuity also contributes to the efficiency of carbohydrate-active enzymes.<br />
<br />
=== CBMs and Multivalency ===<br />
<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
#Lammerts2005 pmid=15501830<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8922Carbohydrate-binding modules2013-07-15T09:11:12Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin. A family CBM41 can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen) <cite>Lammerts2007</cite>. The flexibility of CBM ligand recognition due to ligand promiscuity also contributes to the efficiency of carbohydrate-active enzymes.<br />
<br />
=== CBMs and Multivalency ===<br />
<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase from [[GH13]] created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8921Carbohydrate-binding modules2013-07-15T09:09:09Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
CBM-carbohydrate interactions in general are quite weak (K<sub>a</sub> affinities in mM<sup>-1</sup> to uM<sup>-1</sup> range) making the interaction easily reversible. This feature allows for "recycling" of the appended enzyme to bind to a new region on the substrate once catalysis has been completed at a given site. <br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs have become adapted to recognize more than one type of monosaccharide or glycosidic bond linkage within the binding pocket, a feature called CBM promiscuity. For example a family CBM32 from ''Clostridium perfringens'' NagH binds N-acetyl-glucosamine in the primary subsite but can accommodate N-acetyl-galactosamine or mannose in the secondary site <cite>Ficko20092</cite>. There are several examples of ligand promiscuity within family [[CBM32]]. In plant cell wall recognizing CBMs, they are often able to accommodate both cellulose and hemicelluloses. For example, several family CBM6 members interact with cellulose, xylose or laminarin. A family CBM41 can accommodate both alpha-1,4- and alpha-1,6-linked glucose found in amylopectin (from starch/glycogen). The flexibility of CBM ligand recognition due to ligand promiscuity also contributes to the efficiency of carbohydrate-active enzymes.<br />
<br />
=== CBMs and Multivalency ===<br />
<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
#Ficko20092 pmid=19422833<br />
#Lammerts2007 pmid=17095014<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8920Carbohydrate-binding modules2013-07-12T14:59:05Z<p>Alicia Lammerts van Bueren: starch reference</p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs in the beta-sandwich fold family exhibiting dual binding sites such as CBM6 <cite>Pires2004</cite> and dual starch-binding sites in CBM20 <cite>Lawson1994</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
<br />
<br />
== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
<br />
*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
<br />
*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
<br />
An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
<br />
*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
<br />
*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
<br />
===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
<br />
CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
<br />
''CBM Promiscuity''<br />
<br />
Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs feature promiscuity in ligand recognition. While the core monosaccharide in the primary subsite remains important for initial recognition of carbohydrate ligand, CBMs may exhibit flexibility in what sugar monomers can be accommodated in binding subsites. Examples include... <br />
<br />
=== CBMs and Multivalency ===<br />
<br />
<br />
=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
<br />
The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
<br />
Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
<br />
An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
<br />
== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
<br />
Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
<br />
==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
<br />
Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
<br />
==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
<br />
*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
<br />
*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
<br />
*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
<br />
*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
<br />
*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
<br />
*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
<br />
*Starch binding CBMs added onto transglucosylating enzyme CGTase created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
<br />
<br />
<br />
== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
#Lawson1994 pmid=8107143<br />
</biblio><br />
<br />
[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=Carbohydrate-binding_modules&diff=8919Carbohydrate-binding modules2013-07-12T14:02:26Z<p>Alicia Lammerts van Bueren: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Alicia Lammerts van Bueren^^^<br />
* [[Responsible Curator]]: ^^^Al Boraston^^^ and ^^^Spencer Williams^^^<br />
----<br />
<br />
This page is under construction. In the meantime, please see these references for an essential introduction to the CAZy classification system: <cite>DaviesSinnott2008 Cantarel2009</cite>. CBMs, in particular, have been extensively reviewed<cite>Boraston2004 Hashimoto2006 Shoseyov2006 Guillen2010</cite>.<br />
<br />
<br />
== Overview ==<br />
[[Image:MvGH33modularity3.jpg||thumb|right|300px|'''Figure 1. An example of modularity in a CBM-containing glycoside hydrolase.''' Sialidase from ''Micromonospora viridifaciens'' contains an N-terminal [[CBM32]] (red) X20 linker (yellow) and a C-terminal catalytic [[GH33]] module (green)<cite>Gaskell1995</cite>. Graphical representation of modularity in amino acid sequence (top) and 3D crystal structure (bottom) PDB ID [{{PDBlink}}1eut 1eut].]]<br />
Carbohydrate-binding modules (CBMs) are defined as a stretch of amino acid sequence within a larger encoded protein sequence and fold into a discreet and independent module, forming part of a larger multi-modular protein (Figure 1).<br />
The role of a CBM is to bind to carbohydrate ligand and direct the catalytic machinery onto its substrate, thus enhancing the catalytic efficiency of the multimodular carbohydrate-active enzyme. CBMs are themselves devoid of any catalytic activity. CBMs are most commonly associated with [[Glycoside Hydrolases]] but have also been identified in [[:Category:Polysaccharide_Lyase_Families|Polysaccharide Lyases]], [[Auxiliary_Activity_Families|polysaccharide oxidases]], [[Glycosyltransferases]] and plant cell wall-binding expansins <cite>Georgelis2011</cite>.<br />
<br />
CBMs themselves do not undergo any conformational changes when binding ligand. Rather, the topography of the carbohydrate-binding site is preformed to be complementary to the shape of the target ligand (see [[#Types|Types]]). This is achieved by the presence of amino acid side chains and loops within the CBM binding pocket. However multimodular enzymes as a whole may be quite flexible and experience complete conformational changes when binding substrate. Flexible loop regions between adjacent modules can allow for shifts in the orientation and direction of the catalytic module with respect to the CBM on the target substrate <cite>Ficko2009</cite>. <br />
<br />
==History of CBMs==<br />
CBMs were initially characterized as cellulose binding domains (CBDs) in cellobiohydrolases CBHI and CBHII from ''Trichoderma reesei'' <cite>VanTilbeurgh1986 Tomme1988</cite> and cellulases CenA and CexA from ''Cellulomonas fimi'' <cite>Gilkes1988</cite>. Limited proteolysis experiments of these enzymes yielded truncated enzyme products that showed a reduced or complete loss in their ability to hydrolyze cellulose substrates. The reduction in enzymatic activity was attributed to the loss of ~100 amino acid C-terminal domains which prevented the adsorbption of the enzymes onto cellulose substrate. Thus it was proposed that these independent "domains" are critical for targeting the enzymes onto its substrate and enhancing their hydrolytic activity.<br />
<br />
CBDs were previously categorized into 13 Types based on amino acid sequence similarities <cite>Tomme1995</cite>. This classification system became complicated when similar functional domains from non-cellulolytic carbohydrate-active enzymes were discovered that did not bind cellulose but met all of the [[#Criteria for Defining a new CBM family|criteria]] of a CBD. The term carbohydrate-binding module was proposed to solve this problem to be inclusive of all ancillary modules with non-catalytic carbohydrate-binding function (for a review see <cite>Boraston2004</cite>).<br />
<br />
== Classification ==<br />
=== Sequence Based Classification ===<br />
Carbohydrate-binding modules are currently classified into 67 families based on amino acid sequence similarities (May 2013), which are available through the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. Sequence-based relationships often cluster together modules with similar structural folds and carbohydrate-binding function. While this is true for most CBM families, there are several families that exhibit diversity in the carbohydrate ligands they target (examples include CBM6, [[CBM32]]).<br />
<br />
=== Fold ===<br />
[[Image:CBMfold.jpg|thumb|right|500px|'''Figure 2. Classical CBM beta-sandwich fold.''' C-terminal family CBM27 from ''Thermotoga maritima''mannanase, a Type B CBM (A)(side and front view, PDB ID [{{PDBlink}}1OF4 1OF4]) <cite>Boraston20031</cite> and C-terminal family CBM6 from''Clostridium stercorarium'' xylanase (B) (PDB ID [{{PDBlink}}1NAE 1NAE]) <cite>Boraston20032</cite> showing binding sites on the face (A) and edge (B) of the beta sandwich fold respectively.]]<br />
Structural information for 54 of the 67 CBM families is known. CBMs fall into one of 7 fold families <cite>Boraston2004</cite>. The most common fold exhibited by CBMs is the beta-sandwich fold which is comprised of two overlapping beta-sheets consisting of three to six antiparallel beta strands (Figure 2). The ligand binding site is located primarily on the same face of a beta-sheet (Figure 2A), but may also be positioned on the edge of the beta-sheet within the joining loop region (Figure 2B). There are examples of CBMs with a beta-sandwich fold exhibiting dual binding sites <cite>Pires2004</cite>. Other fold families include the beta-trefoil fold, cysteine knot, OB fold, the hevein and hevein-like and unique folds <cite>Boraston2004</cite>. CBMs of the beta-trefoil fold family (CBM13, CBM42) present multivalent sugar-binding sites, as demonstrated for their interaction with xylan and arabinoxylan respectively <cite>Fujimoto2013</cite>.<br />
<br />
=== Types ===<br />
[[Image:TypeAsurface.png|thumb|right|400px|'''Figure 3. CBM Types.''' (A) Schematic of different CBM Types binding with different regions of a polysaccharide substrate. (B) Type A CBM2b from ''Pyrococcus furiosis'' [[GH18]] chitinase(PDB ID [{{PDBlink}}2CRW 2CRW]) <cite>Nakamura2008</cite>. Aromatic side chains of Type A CBMs form the planar binding surface.]]<br />
CBMs are classified into three main Types defined by the shape and degree of polymerization of their target ligand (Figure 3A). The architecture of the binding site determines what region within a polysaccharide the enzyme will [[#Functional Roles of CBMs|target]]. A recent review on CBM plant cell wall recognition <cite>Gilbert2013</cite> has modified the classification of CBM Types to be as follows: <br />
* Type A: bind to crystalline surfaces of cellulose and chitin (example families CBM1, CBM2, CBM3, CBM5, CBM10). Their binding sites are planar and rich in aromatic amino acid residues creating a flat platform to bind to the flat polycrystalline chitin/cellulose surface (Figure 3B). Type A CBMs are unique and differ significantly from Type B or C.<br />
* Type B: bind internal glycan chains (''endo''-type). The most abundant CBM type. Type B binding sites appear as extended grooves or clefts comprised of binding subsites to accommodate longer sugar chains with four or more monosaccharide units (see Figure 2A for an example). <br />
* Type C: bind termini of glycans (reducing/non-reducing ends, ''exo''-type). Type C binding sites are short pockets for recognizing short sugar ligands containing one to three monosaccharide units (example families CBM9, CBM13, [[CBM32]], CBM47). Families containing Type C CBMs often include lectins as members. <br />
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== Properties of CBM Carbohydrate Binding Interactions ==<br />
=== Functional Roles of CBMs ===<br />
CBMs carry out four main functional roles: <br />
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*''Targeting Effect'': CBMs target the enzyme to distinct regions within a larger macromolecular polysaccharide substrate (reducing end, non-reducing end, internal polysaccharide chains), depending on the architecture of its binding site (see [[#Types|Types]]). <br />
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*''Proximity Effect'': CBMs increase the concentration of enzyme in close proximity to its polysaccharide substrate. This leads to more rapid and efficient substrate degradation. <br />
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An excellent example demonstrating targeting and proximity effects of plant cell wall specific CBMs is available <cite>Herve2010</cite>. <br />
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*''Disruptive Effect'': Some CBMs have been shown to disrupt the surface of tightly packed polysaccharides, such as cellulose fibres and starch granules, causing the substrate to loosen and become more exposed to the catalytic module for more efficient degradation. Disruptive roles have been described for cellulose binding CBM2a <cite>Din1991</cite> and CBM44 <cite>Gourlay2012</cite>. Dual starch-binding domains of family CBM20 from ''Aspergillus niger'' glucoamylase have been shown to disrupt the surface of starch <cite>Southall1999</cite> while dual-associated CBM41 modules may have a disruptive role in degrading glycogen granules <cite>vanBueren2007</cite>. CBM33 was thought to have a disruptive effect on chitin, however these have now been reclassified as Copper-dependent lytic polysaccharide monooxygenases <cite>Vaaje2010</cite> and are reclassified as [[Auxillary Activity Family 9]]. <br />
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*''Adhesion'': CBMs have been shown to adhere enzymes onto the surface of bacterial cell wall components while exhibiting catalytic activity on an external neighboring carbohydrate substrate. For example, CBM35 modules have been shown to interact with the surface glucuronic acid containing sugars in the cell wall of ''Amycolatopsis orientalis'' while the catalytic module is active on external chitosan likely originating from the cell wall of competing soil fungal species <cite>Montanier2009</cite>. <br />
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===Driving Forces of CBM/Carbohydrate Interactions===<br />
There are two key features that drive CBM/carbohydrate interactions. Extensive hydrogen bonding occurs between the hydroxyl groups of carbohydrate ligands and polar amino acid residues within the binding site. Additional water-mediated hydrogen bonding networks between these groups can also be found in the binding site. By far the most important characteristic driving force mediating protein-carbohydrate interactions is the position and orientation of aromatic amino acid residues (Try, Tyr and sometimes Phe) within the binding site. These essential planar residues form hydrophobic stacking interactions with the planar face of sugar rings. Weak intermolecular electrostatic interactions occur between C-H and pi electrons in the planar ring systems and contribute 1.5 - 2.5 kcal/mol energy to the binding reaction <cite>Meyer2003</cite>.<br />
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CBMs may also use coordinated metal ions within the binding site to directly interact with their target ligand. For example, families CBM36 <cite>Jamal2004</cite> and CBM60 <cite>Montanier2010</cite> exhibit calcium-dependent binding to xylooligosaccharides.<br />
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''CBM Promiscuity''<br />
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Because of the diversity of carbohydrate structures and motifs found in plant and mammalian glycans, some CBMs feature promiscuity in ligand recognition. While the core monosaccharide in the primary subsite remains important for initial recognition of carbohydrate ligand, CBMs may exhibit flexibility in what sugar monomers can be accommodated in binding subsites. Examples include... <br />
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=== CBMs and Multivalency ===<br />
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=== CBMs and Lectins ===<br />
Several lectins <cite>SharonLis2004 SharonLis2007</cite> fall into the CBM classification system in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database] as they exhibit similar folds and carbohydrate binding properties with CBMs. For example, ricin toxin B chain from ''Ricinus communis'' resides in family [[CBM13]], while wheat germ agglutinin (WGA) can be found in family [[CBM18]]. The human lectin malectin is classified as family CBM57 and plays a role in N-linked glycan processing of polypeptides in the endoplasmic reticulum <cite>Galli2011</cite>. CBMs also share properties with lectins that are not yet incorporated in the [http://www.cazy.org/Carbohydrate-Binding-Modules.html Carbohydrate Active enZyme database]. For example the fucose-specific Anquila anguila lectin AAA is similar to Type C CBMs found in family [[CBM6]] and [[CBM32]] <cite>Boraston20032</cite>. Lectins which are classified as CBMs are incorporated into a family because they were found to share amino acid sequence identity with a known CBM appended to a carbohydrate-active enzyme (see [[#Criteria for Defining a new CBM family|criteria]]). <br />
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The most prominent feature that separates CBMs from lectins is the involvement of lectins in agglutination of sugar-containing molecules or glycoconjugates. Lectins often form quaternary structures as homodimers, trimers or tetramers with several binding sites which then agglutinate the target glycocongugate <cite>SharonLis2004 SharonLis2007</cite>. CBMs themselves are not involved in the formation of quaternary structures and do not have agglutinating properties. <br />
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Lectins are also thought to have a higher density of hydrogen bond formation with their carbohydrate ligand than CBMs and may differ in their ability to utilize thermodynamic contributions from solvent rearrangement during ligand binding (references).<br />
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An excellent, brief historical overview of the discovery and characterization of lectins is available <cite>SharonLis2004</cite>.<br />
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== Criteria for Defining a new CBM family ==<br />
In order to define a new CBM family, one must:<br />
# Demonstrate an independent module as part of a larger carbohydrate-active enzyme.<br />
# Demonstrate binding to carbohydrate ligand.<br />
# Additional family members are then determined based on amino acid sequence similarity. To be defined as a true CBM, it must form part of a larger amino acid sequence encoding a putative CAZyme (or enzyme with demonstrated activity on a carbohydrate-containing substrate and the CBM enhances the catalytic efficiency of the enzyme by binding with or in close proximity of the substrate). <br />
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Amino acid sequence-based classification of a CBM family may lead to the incorporation of other carbohydrate binding proteins within a given family, including lectins (such as ricin (CBM13), tachycitin (CBM14), wheat germ agglutinin (CBM18), fucolectin (CBM47), and malectin (CBM57)) and periplasmic solute binding proteins (such as [[CBM32]]). The community is open to incorporation of all carbohydrate-binding proteins within the CBM classification system based on the above criteria.<br />
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==Studying CBM-ligand Interactions==<br />
A great review on laboratory approaches to studying the binding function of carbohydrate-binding modules is available <cite>Abbott2012</cite>. Typically, molecular biology techniques are used to overproduce a CBM protein in a host strain such as ''Escherichia coli'' which is then isolated and purified. Initial screening for carbohydrate binding interactions can be performed using screening techniques such as microarrays <cite>vanBueren2007</cite> or fluorescence microscopy techniques <cite>vanBueren2007 McCartney2006 Herve2010</cite>. Several approaches can be taken to verify and quantify CBM-polysaccharide interaction, including affinity gel electrophoresis, UV difference and fluorescence spectroscopy, solid state depletion assay and isothermal titration calorimetry <cite>Lammerts2004</cite>. <br />
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Overall demonstration of carbohydrate binding function by CBMs is essential to understanding how these associated modules confer enzymatic specificity to carbohydrate-active enzymes. <br />
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==Biotechnological applications of CBMs==<br />
CBMs and their carbohydrate-binding properties are used for many different biological applications. Below is listed several examples.<br />
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*Features of CBMs are currently being exploited to create designer CAZymes with enhanced or modified carbohydrate recognition functions <cite>MkKee2012 Cuskin2012 McKee2012 Tang2013</cite>.<br />
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*Family CBM9 can be used as an affinity tag to purify tagged proteins on a cellulose-based affinity column <cite>Kavoosi2004</cite>.<br />
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*CBMs are used as molecular probes to detect presence of specific carbohydrate motifs in plant <cite>McCartney2006 Herve2010</cite> and mammalian tissues <cite> Lammerts2007 Boraston2006</cite>.<br />
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*CBMs are used in fibre modification. Engineered CBMs have been shown to increase the strength of cellulose pulp in paper-making processes <cite>Levy2003 Yokota2009</cite>, in crosslinking polysaccharide fibres for biomaterials <cite>Levy2004</cite> and cotton fibre modification <cite>Zhang2011</cite>.<br />
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*There are several examples of CBMs being used to immobilize whole cells onto carbohydrate surfaces <cite>Francisco1993 Simsek2013 Wang2006</cite>.<br />
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*CBMs are used to enhance bioprocessing enzymes for industrial uses in pulp processing and biofuel production <cite>Reyes2013 Gourlay2012 Ravalason2009</cite>.<br />
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*Starch binding CBMs added onto transglucosylating enzyme CGTase created a fusion enzyme with more efficient transglucosylating activity with soluble starch, important for industrial biotransformation processes <cite>Han2013</cite>.<br />
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== References ==<br />
<biblio><br />
#Tomme1988 pmid=3338453<br />
#VanTilbeurgh1986 Van Tilbeurgh, H., Tomme P., Claeyssens M., Bhikhabhai R., Pettersson G.(1986) Limited proteolysis of the cellobiohydrolase I from Trichoderma reesei. FEBS Lett. 204,223–227. [http://dx.doi.org/10.1016/0014-5793(86)80816-X]<br />
#Gilkes1988 pmid=3134347<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. Biochem. J. (BJ Classic Paper, online only). [http://dx.doi.org/10.1042/BJ20080382 DOI: 10.1042/BJ20080382]<br />
#Boraston2004 pmid=15214846<br />
#Hashimoto2006 pmid=17131061<br />
#Shoseyov2006 pmid=16760304<br />
#Guillen2010 pmid=19908036<br />
#Meyer2003 pmid=12645054<br />
#Abbott2012 pmid=22608728<br />
#vanBueren2007 pmid=17187076<br />
#Lammerts2004 pmid=15223327<br />
#McCartney2006 pmid=16537424<br />
#Tomme1995 Tomme, P., Warren, R.A., Miller, R.C., Jr., Kilburn, D.G. & Gilkes, N.R. (1995) in Enzymatic Degradation of Insoluble Polysaccharides (Saddler, J.N. & Penner, M., eds.), Cellulose-binding domains: classification and properties. pp. 142-163, American Chemical Society, Washington.<br />
#Ficko2009 pmid=19193644<br />
#Gilbert2013 pmid=23769966<br />
#Herve2010 pmid=20696902<br />
#Cuskin2012 pmid=23213210<br />
#Gaskell1995 pmid=8591030<br />
#Vaaje2010 pmid=20929773<br />
#Georgelis2011 pmid=21454649<br />
#Pires2004 pmid=15010454<br />
#Boraston20031 pmid=12791255<br />
#Boraston20032 pmid=12634060<br />
#Montanier2009 pmid=19218457<br />
#Din1991 Din, N., Gilkes, N.R., Tekant, B., Miller, R.C., Jr., Warren, R.A., and Kilburn, D.G. (1991) Non-Hydrolytic Disruption of Cellulose Fibres by the Binding Domain of a Bacterial Cellulase. Nat. Biotech. 9, 1096 - 1099. http://doi:10.1038/nbt1191-1096<br />
#Gourlay2012 pmid=22828270<br />
#Nakamura2008 pmid=18582475<br />
#Galli2011 pmid=21298103<br />
#SharonLis2004 pmid=15229195<br />
#SharonLis2007 isbn=9781402066054<br />
#Fujimoto2013 pmid=23832347<br />
#Jamal2004 pmid=15242594<br />
#Montanier2010 pmid=20659893<br />
#Southall1999 pmid=10218582<br />
#McKee2012 pmid=22492980<br />
#Kavoosi2004 pmid=15177165<br />
#Boraston2006 pmid=16987809<br />
#Levy2003 Levy, I., Paldi, T., Siegel, D., and Shoseyov, O. (2003) Cellulose binding domain from Clostridium cellulovorans as a paper modification reagent. Nordic Pulp Paper Res. J. 18:421-428.<br />
#Levy2004 pmid=14738848<br />
#Yokota2009 Yokota, S., Matuso, K., Kitaoka, T., and Wariishi, H. (2009) Retention and paper strength characteristics of anionic polyacrylamides conjugated with carbohydrate-binding modules. "Carbohydrate-binding anionic PAM". [http://ojs.cnr.ncsu.edu/index.php/BioRes/article/view/BioRes_04_1_0234_Yokota_MKW_Carohydr_Binding_aPAM/314 BioResources] 4(1):234-244.<br />
#Zhang2011 Zhang, Y., Chen, S., He, M., Wu, J., Chen, J., and Wang, Q. (2011) Effects of Thermobifida fusca Cutinase-carbohydrate-binding Module Fusion Proteins on Cotton Bioscouring. Biotechnology and Bioprocess Engineering. 16,645-653 http://DOI:10.1007/s12257-011-0036-4<br />
#Francisco1993 pmid=7763519<br />
#Simsek2013 pmid=23354445<br />
#Wang2006 pmid=16391137<br />
#Reyes2013 pmid=23819686<br />
#Tang2013 pmid=23741390<br />
#Ravalason2009 pmid=19414054<br />
#Han2013 pmid=23503312<br />
</biblio><br />
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[[Category:Definitions and explanations]]</div>Alicia Lammerts van Buerenhttps://www.cazypedia.org/index.php?title=File:TypeAsurface.png&diff=8918File:TypeAsurface.png2013-07-12T14:00:44Z<p>Alicia Lammerts van Bueren: Alicia Lammerts van Bueren uploaded a new version of &quot;File:TypeAsurface.png&quot;</p>
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