https://www.cazypedia.org/api.php?action=feedcontributions&feedformat=atom&user=Anthony+ClarkeCAZypedia - User contributions [en-ca]2026-05-04T21:20:34ZUser contributionsMediaWiki 1.35.10https://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=4202Glycoside Hydrolase Family 232010-03-06T23:32:18Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglycosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The stereochemistry of the reaction catalysed by the family G lysozymes has been determined experimentally as inverting <cite>10</cite>. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>8</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>12</cite> or bulgecin <cite>11</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#10 pmid=10430876<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#12 pmid=7479697<br />
#11 pmid=7548026<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=4201Glycoside Hydrolase Family 232010-03-06T23:24:48Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglycosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The stereochemistry of the reaction catalysed by the family G lysozymes has been determined experimentally as inverting <cite>10</cite>. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>8</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>12</cite> or bulgecin <cite>11</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#10 pmid=10430876<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#12 pmid=7479697<br />
#11 pmid=7548026<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=4200Glycoside Hydrolase Family 232010-03-06T23:16:20Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglycosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>12</cite> or bulgecin <cite>11</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#12 pmid=7479697<br />
#11 pmid=7548026<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=4199Glycoside Hydrolase Family 232010-03-06T23:14:36Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglycosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>8</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>12</cite> or bulgecin <cite>11</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#12 pmid=7479697<br />
#11 pmid=7548026<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=4198Glycoside Hydrolase Family 232010-03-06T23:10:40Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglycosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>12</cite> or bulgecin <cite>11</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#12 pmid=7479697<br />
#11 pmid=7548026<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=4197Glycoside Hydrolase Family 232010-03-06T23:09:02Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglycosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>12</cite> or bulgecin <cite>11</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#11 pmid=7548026<br />
#12 pmid=7479697<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4063Glycoside Hydrolase Family 1042010-02-21T18:19:56Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
α+β “lysozyme fold<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in lambda bacteriophage lytic transglycosylase has been inferred as Glu19 by X-ray crystallography of the enzyme alone <cite>3</cite> and in complex with two chitohexaose oligomers <cite>4</cite>. The role of an essential carboxyl group in the enzyme was confirmed by chemical modification <cite>4</cite>, thus supporting the identification of Glu19. The mechanism of action of the family GH104 enzymes has not been investigated and hence it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>3 4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Bacteriophage lambda <cite>3</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of lambda bacteriophage <cite>3</cite>.<br />
;First 3-D structure: Lambda bacteriophage <cite>3</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=9514719 <br />
#4 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4062Glycoside Hydrolase Family 1042010-02-21T18:18:49Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
α+β “lysozyme fold<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in lambda bacteriophage lytic transglycosylase has been inferred as Glu19 by X-ray crystallography of the enzyme alone <cite>3</cite> and in complex with two chitohexaose oligomers <cite>4</cite>. The role of an essential carboxyl group in the enzyme was confirmed by chemical modification <cite>4</cite>, thus supporting the identification of Glu19. The mechanism of action of the family GH104 enzymes has not been investigated and hence it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>3 4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Bacteriophage lambda <cite>3</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of lambda bacteriophage <cite>3</cite>.<br />
;First 3-D structure: Lambda bacteriophage <cite>3</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=9514719 <br />
#4 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4061Glycoside Hydrolase Family 1042010-02-21T17:45:34Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in lambda bacteriophage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Bacteriophage lambda <cite>3</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of lambda bacteriophage <cite>3</cite>.<br />
;First 3-D structure: Lambda bacteriophage <cite>3</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=9514719 <br />
#4 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4060Glycoside Hydrolase Family 1042010-02-21T17:41:49Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
[[Image:filename|thumb|widthpx| ]]<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in lambda bacteriophage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Bacteriophage lambda <cite>3</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of lambda bacteriophage <cite>3</cite>.<br />
;First 3-D structure: Lambda bacteriophage <cite>3</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=9514719 <br />
#4 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=File:LT-GEWL.jpg&diff=4059File:LT-GEWL.jpg2010-02-21T17:41:25Z<p>Anthony Clarke: uploaded a new version of "File:LT-GEWL.jpg"</p>
<hr />
<div></div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=File:LTreaction.jpg&diff=4058File:LTreaction.jpg2010-02-21T17:37:18Z<p>Anthony Clarke: uploaded a new version of "File:LTreaction.jpg"</p>
<hr />
<div></div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4057Glycoside Hydrolase Family 1042010-02-21T05:11:28Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in lambda bacteriophage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Bacteriophage lambda <cite>3</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of lambda bacteriophage <cite>3</cite>.<br />
;First 3-D structure: Lambda bacteriophage <cite>3</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=9514719 <br />
#4 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4056Glycoside Hydrolase Family 1042010-02-21T05:04:21Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''lambda'' phage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Bacteriophage ''lambda'' <cite>3</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''lambda'' phage <cite>3</cite>.<br />
;First 3-D structure: ''lambda'' phage <cite>3</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4055Glycoside Hydrolase Family 1042010-02-21T05:01:15Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. Unfortunately, the origin of many of the hypothetical enzymes listed in GH104 is misleading because they are encoded within prophages which have been integrated into the chromosome of their bacterial host. In other cases, the phage enzyme has been acquired by pathogenicity islands on the bacterial chromosome. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''lambda'' phage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
<br />
== Family Firsts ==<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4054Glycoside Hydrolase Family 1042010-02-21T04:59:40Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''lambda'' phage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
<br />
== Family Firsts ==<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4053Glycoside Hydrolase Family 1042010-02-21T04:56:36Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''lambda'' phage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_104&diff=4052Glycoside Hydrolase Family 1042010-02-21T04:49:51Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH104 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacteriophage origin and they constitute family 4 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is the enzyme from ''lambda'' phage. <br />
<br />
These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1). No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>2</cite>. No detailed analyses involving either steady state or pre-steady state kinetic studies have been reported.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH103]]), the GH104 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''lambda'' phage lytic transglycosylase has been inferred by X-ray crystallography as Glu19 <cite>3</cite>. The mechanism of action of the family GH104 enzymes has not been investigated and thus it is not known if they follow that of the lytic transglycosylases of families [[GH23]], [[GH102]], or [[GH103]].<br />
<br />
<br />
== Three-dimensional structures ==<br />
The three-dimensional structure of only the lambda phage enzyme has been solved <cite>4</cite>, and like the other lytic transglycosylases of families [[GH23]], and [[GH103]], it possesses the well characterized α+β “lysozyme fold.” <br />
<br />
<br />
== Family Firsts ==<br />
;First sterochemistry determination: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>Comfort2007</cite>.<br />
;First catalytic nucleophile identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>MikesClassic</cite>.<br />
;First general acid/base residue identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>He1999</cite>.<br />
;First 3-D structure: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>3</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=357<br />
#3 pmid=11341831<br />
<br />
</biblio><br />
<br />
<br />
[[Category:Glycoside Hydrolase Families|GH104]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4051Glycoside Hydrolase Family 1032010-02-20T03:09:33Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:MltBmechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' and ''P. aeruginosa'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB) and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism has been invoked analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu162 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline (Figure 2) was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several family GH103 enzymes, the first solved being that of ''E. coli'' MltB (Slt35) <cite>5</cite>. The catalytic domain of the enyzmes possesses the well characterized α+β "lysozyme fold." <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4050Glycoside Hydrolase Family 1022010-02-20T03:09:02Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|none<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH103 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4049Glycoside Hydrolase Family 1022010-02-20T03:08:48Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|None<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH103 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4048Glycoside Hydrolase Family 1032010-02-20T03:07:42Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|None<br />
α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:MltBmechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' and ''P. aeruginosa'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB) and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism has been invoked analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu162 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline (Figure 2) was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several family GH103 enzymes, the first solved being that of ''E. coli'' MltB (Slt35) <cite>5</cite>. The catalytic domain of the enyzmes possesses the well characterized α+β "lysozyme fold." <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4047Glycoside Hydrolase Family 1032010-02-20T03:06:02Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:MltBmechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' and ''P. aeruginosa'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB) and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism has been invoked analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu162 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline (Figure 2) was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several family GH103 enzymes, the first solved being that of ''E. coli'' MltB (Slt35) <cite>5</cite>. The catalytic domain of the enyzmes possesses the well characterized α+β "lysozyme fold." <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4046Glycoside Hydrolase Family 1032010-02-20T03:04:53Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:MltBmechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' and ''P. aeruginosa'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB) and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism has been invoked analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu162 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline (Figure 2) was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several family GH103 enzymes, the first solved being that of ''E. coli'' MltB (Slt35) <cite>5</cite>. The catalytic domain of the enyzmes possesses the well characterized α+β "lysozyme fold." <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4045Glycoside Hydrolase Family 1032010-02-20T03:03:22Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known/not known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:MltBmechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' and ''P. aeruginosa'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB) and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism has been invoked analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu162 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline (Figure 2) was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several family GH103 enzymes, the first solved being that of ''E. coli'' MltB (Slt35) <cite>5</cite>. The catalytic domain of the enyzmes possesses the well characterized α+β "lysozyme fold." <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
#11 pmid=<br />
#12 pmid=<br />
#13 pmid=<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4044Glycoside Hydrolase Family 1032010-02-20T02:57:29Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known/not known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:MltBmechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB)and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases, has been invoked <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu162 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline (Figure 2) was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several family GH103 enzymes, the first solved being that of ''E. coli'' MltB (Slt35) <cite>5</cite>. The catalytic domain of the enyzmes possesses the well characterized α+β "lysozyme fold." <br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
#11 pmid=<br />
#12 pmid=<br />
#13 pmid=<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=File:MltBmechanism.jpg&diff=4043File:MltBmechanism.jpg2010-02-20T02:56:08Z<p>Anthony Clarke: </p>
<hr />
<div></div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4042Glycoside Hydrolase Family 1032010-02-20T02:31:45Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known/not known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB)and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases, has been invoked <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite>, and the results of a site-directed mutagenesis study suggest that Ser216 orients the N-acetyl group on MurNAc at the -1 subsite of MltB for its participation in a substrate-assisted mechanism of action <cite>8</cite>.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Content is to be added here.<br />
<br />
<br />
== Family Firsts ==<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltB from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltB <cite>5</cite>.<br />
;First 3-D structure: ''E. coli'' MltB <cite>5</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltB <cite>9</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltB <cite>9</cite>.<br />
;Frist demonstration of molecular interactions between GH103 enzymes and penicillin-binding proteins:''E. coli'' MltB <cite>10</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=17910958<br />
#9 pmid=7476170<br />
#10 pmid=9158739<br />
#11 pmid=<br />
#12 pmid=<br />
#13 pmid=<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_103&diff=4041Glycoside Hydrolase Family 1032010-02-20T02:12:27Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known/not known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH103 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 3 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase B (MltB) from ''Escherichia coli'' <cite>2</cite>. These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''Pseudomonas aeruginosa'' MltB acting on insoluble peptidoglycan sacculi <cite>4</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltB. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH102]], and [[GH104]]), the GH103 enzymes are thought to possess a single catalytic acid/base residue. This residue has been identified as Glu162 in MltB from both ''E. coli'' and ''P. aeruginosa'' and, indeed, its replacement abolishes catalytic activity <cite>4 5</cite>. The mechanism of action of family GH103 enzymes has been investigated the most compared to the lytic transglycosylases of the other families ([[GH23]],[[GH102]], and [[GH104]]). <br />
<br />
Examination of crystal structures of ''E. coli'' Slt35 (a soluble proteolytic derivative of MltB)and theoretical considerations led to the proposal of a mechanism that accommodates a single catalytic at its active site. Thus, based on the complexes formed with murodipeptide, chitobiose, and the inhibitor bulgecin, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases, family [[GH20]] ''N''-acetyl-β-hexosaminidases, and family [[GH23]] lytic transglycosylases, has been invoked <cite>6</cite>. Thus, the catalytic Glu162 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. The β-hexosaminidase inhibitor NAG-thiazoline was found to inhibit ''P. aeruginosa'' MltB thus supporting the proposal for the formation of an oxazolinium ion intermediate <cite>7</cite><br />
<br />
<br />
== Three-dimensional structures ==<br />
Content is to be added here.<br />
<br />
<br />
== Family Firsts ==<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=1356966<br />
#3 pmid=357<br />
#4 pmid=11790124<br />
#5 pmid=10545329<br />
#6 pmid=10684641<br />
#7 pmid=15358542<br />
#8 pmid=<br />
#9 pmid=<br />
#10 pmid= <br />
#11 pmid=<br />
#12 pmid=<br />
#13 pmid=<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH103]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4040Glycoside Hydrolase Family 1022010-02-20T01:05:34Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH103 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4039Glycoside Hydrolase Family 1022010-02-19T23:18:04Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite>.<br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4038Glycoside Hydrolase Family 1022010-02-19T23:17:03Z<p>Anthony Clarke: /* Substrate specificities */</p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite><br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4037Glycoside Hydrolase Family 1022010-02-19T23:16:48Z<p>Anthony Clarke: /* Catalytic Residues */</p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite><br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4036Glycoside Hydrolase Family 1022010-02-19T23:16:29Z<p>Anthony Clarke: /* Kinetics and Mechanism */</p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite><br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4035Glycoside Hydrolase Family 1022010-02-19T23:15:57Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4034Glycoside Hydrolase Family 1022010-02-19T23:14:54Z<p>Anthony Clarke: </p>
<hr />
<div>[[Image:filename|thumb|widthpx| ]]<!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=File:Mltamechanism.jpg&diff=4033File:Mltamechanism.jpg2010-02-19T23:14:26Z<p>Anthony Clarke: uploaded a new version of "File:Mltamechanism.jpg"</p>
<hr />
<div></div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=File:Mltamechanism.jpg&diff=4032File:Mltamechanism.jpg2010-02-19T23:12:43Z<p>Anthony Clarke: </p>
<hr />
<div></div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4031Glycoside Hydrolase Family 1022010-02-19T23:12:42Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
[[Image:Mltamechanism.jpg|thumb|right|'''Figure 2.''' Reaction mechanism proposed for ''E. coli'' MltA. (''click to enlarge'').]]As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4030Glycoside Hydrolase Family 1022010-02-19T22:44:18Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the putative transition state oxocarbenium ion by an alpha-helix dipole <cite>5</cite>. Thus, the catalytic Asp308 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of a transition intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity, this oxocarbenium intermediate is proposed to be stabilized by the negatively-charged side of the dipole that would exist at the C-terminal end of an alpha helix positioned just below the -1 binding subsite. This would be followed by abstraction of the C-6 hydroxyl proton of the intermediate involving Asp308 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4029Glycoside Hydrolase Family 1022010-02-19T22:32:06Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product (Figure 1) thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the transition state oxocarbenium ion by by an alpha-helix dipole <cite>5</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4028Glycoside Hydrolase Family 1022010-02-19T22:30:49Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the transition state oxocarbenium ion by by an alpha-helix dipole <cite>5</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4027Glycoside Hydrolase Family 1022010-02-19T22:30:07Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
[[Image:LTreaction.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]]The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
<br />
== Kinetics and Mechanism ==<br />
The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the transition state oxocarbenium ion by by an alpha-helix dipole <cite>5</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=File:LTreaction.jpg&diff=4026File:LTreaction.jpg2010-02-19T22:26:16Z<p>Anthony Clarke: </p>
<hr />
<div></div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4025Glycoside Hydrolase Family 1022010-02-19T22:20:34Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Reaction catalyzed by family GH102 enzymes. LT, lytic transglycosylase. (''click to enlarge'').]] The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported, but the Michaelis Menten (''K''<sub>M</sub> and ''V''<sub>max</sub>) parameters have been estimated for ''E. coli'' MltA acting on insoluble peptidoglycan sacculi <cite>2</cite> <br />
<br />
<br />
<br />
<br />
== Catalytic Residues ==<br />
As with other lytic transglycosylases (families [[GH23]], [[GH103]], and [[GH104]]), the GH102 enzymes are thought to possess a single catalytic acid/base residue. This residue in ''E. coli'' MltA has been identified as Asp308 and, indeed, its replacement with Ala abolishes catalytic activity <cite>4</cite>.<br />
<br />
The mechanism of action of the family GH102 enzymes has yet to be proven experimentally, but examination of crystal structures of ''E. coli'' MltA complexed with chitohexoase has led to the proposal of a novel mechanism of action involving the stabilization of the transition state oxocarbenium ion by by an alpha-helix dipole <cite>5</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH102 enzymes, the first solved being that of ''E. coli'' MltA <cite>4</cite>. Unlike the other lytic transglycosylases of families [[GH23]], [[GH103]], and [[GH104]] which possesses the well characterized α+β “lysozyme fold,” these enzymes have a unique structure consisting of two domains. One has a double-ψ β-barrel fold similar to the catalytic domain of the family [[GH45]] endoglucanase V from ''Humicola insolens'' <cite>6</cite>. The second and smaller domain has a β-barrel fold topology. The large groove between the two domains serves as the active site cleft.<br />
<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: MltA from ''E. coli'' <cite>2</cite>.<br />
;First catalytic nucleophile identification: Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of ''E. coli'' MltA <cite>4</cite>.<br />
;First 3-D structure: ''E. coli'' MltA <cite>4</cite>.<br />
;First identification as a lipoprotein: ''E. coli'' MltA <cite>7</cite>.<br />
;First identification of localization to outer membrane: ''E. coli'' MltA <cite>7</cite>.<br />
;Frist demonstration of molecular interactions between GH102 enzymes and penicillin-binding proteins:''E. coli'' MltA <cite>8</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=8288527<br />
#3 pmid=357<br />
#4 pmid=16139297<br />
#5 pmid=17502382<br />
#6 pmid=8377830<br />
#7 pmid=9287002<br />
#8 pmid=10037771<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_102&diff=4024Glycoside Hydrolase Family 1022010-02-19T21:24:19Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GHnn'''<br />
|-<br />
|'''Clan''' <br />
|GH-x<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known/not known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GHnn.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of bacterial origin and they constitute family 2 of the classification scheme of Blackburn and Clarke <cite>1</cite>. The prototype for this family is membrane-bound lytic transglycosylase A (MltA) from ''Escherichia coli.'' These enzymes cleave the β-1,4 linkage between N-acetylmuramoyl and N-acetylglucosaminyl residues in peptidoglycan (Figure 1), but unlike the lytic transglycosylases of other families, they are active on peptidoglycan fragments lacking their stem peptides <cite>2</cite>. No other activities have been observed.<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]] The lytic transglycosidases, strictly speaking, are retaining enzymes. However, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>3</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
Content is to be added here.<br />
<br />
<br />
== Three-dimensional structures ==<br />
Content is to be added here.<br />
<br />
<br />
== Family Firsts ==<br />
;First sterochemistry determination: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>Comfort2007</cite>.<br />
;First catalytic nucleophile identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>MikesClassic</cite>.<br />
;First general acid/base residue identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>He1999</cite>.<br />
;First 3-D structure: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>3</cite>.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#2 pmid=8288527<br />
<br />
<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH102]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=3997Glycoside Hydrolase Family 232010-02-18T16:09:21Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{CuratorApproved}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively. <br />
<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>11</cite> or bulgecin <cite>12</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#11 pmid=7548026<br />
#12 pmid=7479697<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=3996Glycoside Hydrolase Family 232010-02-18T16:07:29Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively. <br />
<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>11</cite> or bulgecin <cite>12</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#11 pmid=7548026<br />
#12 pmid=7479697<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=3995Glycoside Hydrolase Family 232010-02-18T16:06:09Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively. <br />
<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]Until recently, the family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations have led to separate proposals for the two classes of enzymes. <br />
<br />
With the lytic transglycosylases, there is still no evidence for a second catalytic residue at their active sites. Hence, based on the complexes formed with 1,6-anhydromuropeptide <cite>11</cite> or bulgecin <cite>12</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked for the lytic transglycosylases. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite> involving catalytic acid and base residues. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#11 pmid=7548026<br />
#12 pmid=7479697<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarkehttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_23&diff=3994Glycoside Hydrolase Family 232010-02-18T15:41:55Z<p>Anthony Clarke: </p>
<hr />
<div><!-- CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: ^^^Anthony Clarke^^^<br />
* [[Responsible Curator]]: ^^^Anthony Clarke^^^<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" |'''Glycoside Hydrolase Family GH23'''<br />
|-<br />
|'''Clan''' <br />
|none,<br>α+β "lysozyme fold"<br />
|-<br />
|'''Mechanism'''<br />
|retaining/inverting<br />
|-<br />
|'''Active site residues'''<br />
|known<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |http://www.cazy.org/fam/GH23.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
The glycoside hydrolases of this family are lytic transglyosylases (also referred to as peptidoglycan lyases) of both bacterial and bacteriophage origin, and family G lysozymes (EC [{{EClink}}3.2.1.17 3.2.1.17]; muramidase, peptidoglycan ''N''-acetylmuramoylhydrolase, 1,4-β-''N''-acetylmuramidase, ''N''-acetylmuramoylhydrolase) of eukaryotic origin. Both of these enzymes are active on peptidoglycan, but only the lysozymes are active on chitin and chitooligosaccharides. No other activities have been observed.<br />
<br />
The lytic transglycosylases of GH23 constitute Family 1 of the organizational scheme of Blackburn and Clarke <cite>1</cite>. This family has been subdivided into five subfamilies (1A-1E) with ''Escherichia coli'' soluble lytic transglycosylase 70 (Slt70), membrane-bound lytic transglycosylase C (MltC), MltE, MltD, and MltF (formerly, YfhD) serving as the prototypes for families 1A, 1B, 1C, 1D, and 1E, respectively. <br />
<br />
<br />
== Kinetics and Mechanism ==<br />
[[Image:LT-GEWL.jpg|thumb|right|'''Figure 1.''' Lytic and hydrolytic pathways of GH23 enzymes. GEWL, g-type lysozymes; LT, lytic transglycosylase. (''click to enlarge'').]]The enzymes of this family cleave the β-1,4 linkage between ''N''-acetylmuramoyl and ''N''-acetylglucosaminyl residues in peptidoglycan (Figure 1) . Only the lysozymes of this family are capable of releasing ''N''-acetyl-{{Smallcaps|d}}-glucosamine residues from chitodextrins, and neither catalyze (inter) transglycosylation reactions. The mechanism of the family G lysozymes has not been determined experimentally, but theoretical considerations based on crystallographic data <cite>2</cite> and modeling studies <cite>3</cite> suggest that they are inverting enzymes. On the other hand, the lytic transglycosidases, strictly speaking, are retaining enzymes. However, unlike lysozyme, they are not hydrolases but rather catalyse an intramolecular glycosyl transferase reaction onto the C-6 hydroxyl group of the muramoyl residue leading to the generation of a terminal 1,6-anhdyromuramoyl product thus lacking a reducing end <cite>4</cite>. The lytic transglycosylases require the peptide side chains in peptidoglycan for activity, accounting for their inactivity against chitin or chitooligosaccharides <cite>5</cite>. No detailed analyses involving both steady state and pre-steady state kinetic studies have been reported. <br />
<br />
== Catalytic Residues ==<br />
[[Image:LTmechanism.jpg|thumb|right|'''Figure 2.''' Detailed catalytic mechanism of GH23 lytic transglycosylases (''click to enlarge''). ]]The family GH23 enzymes were thought to have only a single catalytic residue at their catalytic centre. The identity of the catalytic acid/base residue of the lysozymes was first inferred by X-ray crystallography of goose egg-white lysozyme (GEWL) as Glu 73 <cite>6 7</cite>. Likewise, analysis of the crystal structure of ''E. coli'' Slt70 identified Glu as the lone catalytic residue<cite>7</cite>. Indeed, replacement of each respective residue results in loss of catalytic activity <cite>9 10</cite>. The mechanism of action of the family GH23 enzymes has yet to be proven experimentally, but examination of crystal structures and theoretical considerations has led to separate proposals for the two classes of enzymes. <br />
<br />
Based on the complexes formed with 1,6-anhydromuropeptide <cite>11</cite> or bulgecin <cite>12</cite>, a substrate-assisted mechanism, analogous to the family [[GH18]] chitinases and chitobiases and family [[GH20]] ''N''-acetyl-β-hexosaminidases, has been invoked for the lytic transglycosylases. Thus, the catalytic Glu73 is proposed to serve initially as an acid catalyst to donate a proton to the glycosidic oxygen of the linkage to be cleaved leading to the formation of an intermediate with oxocarbenium ion character (Figure 2). In the absence of an anion/nucleophile in close proximity to stabilize this oxocarbenium intermediate, the lytic transglycosylases would employ anchimeric assistance of the MurNAc 2-acetamido group resulting in the formation an oxazolinium ion intermediate. This would be followed by abstraction of the C-6 hydroxyl proton of the oxazolinium species involving Glu73 which now serves as the base catalyst leading to nucleophilic attack and the formation of 1,6-anhydromuramic acid product. <br />
<br />
For the g-type lysozymes, recent studies support a typical inverting mechanism of action <cite>2 3</cite>. In fact, it is possible that two catalytic general base residues, a primary and a secondary residue, position a catalytic water molecule and abstract a proton to affect substrate hydrolysis by the single displacement mechanism. With GEWL, Asp97 and Asp86, respectively, are proposed to serve this function while these would be represented by the conserved Asp101 and Asp90 residues in the g-type lysozyme from Atlantic cod fish. Indeed, the double replacement of Asp101 and Asp90 in the cod lysozyme results in over a 300-fold decrease in activity <cite>2</cite>.<br />
<br />
== Three-dimensional structures ==<br />
Three-dimensional structures are available for several Family GH23 enzymes, the first solved being that of GEWL <cite>7 13</cite>. The catalytic domain of each enzyme possesses the well characterized α+β "lysozyme fold" for avian lysozymes. However, there are distinct structural differences between the two classes of enzymes. Most notably, the environment of the active site in lytic transglycosylases, particularly around the catalytic acid/base, is more hydrophobic compared to that of GEWL. This distinction may account for the difference in the reaction mechanisms of the two enzymes.<br />
<br />
== Family Firsts ==<br />
;First identification of lytic transglycosylase: Soluble lytic transglycosylase 70 <cite>4</cite>.<br />
;First catalytic nucleophile identification: For g-type lysozymes <cite>3</cite>; Not applicable for lytic transglycosylases.<br />
;First general acid/base residue identification: Inferred by X-ray crystallography of goose egg-white lysozyme <cite>7</cite>.<br />
;First 3-D structure: Goose egg-white lysozyme <cite>13</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#1 pmid=11139297<br />
#2 pmid=19543850<br />
#3 pmid=18845568<br />
#4 pmid=357<br />
#5 pmid=8405923<br />
#6 pmid=7823320<br />
#7 pmid=6442995 <br />
#8 pmid=10452894<br />
#9 pmid=10545329<br />
#10 pmid=10430876 <br />
#11 pmid=7548026<br />
#12 pmid=7479697<br />
#13 pmid=6866082<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH023]]</div>Anthony Clarke