https://www.cazypedia.org/api.php?action=feedcontributions&feedformat=atom&user=Eduardo+Moreno+PrietoCAZypedia - User contributions [en-ca]2026-05-04T07:52:37ZUser contributionsMediaWiki 1.35.10https://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_57&diff=17938Glycoside Hydrolase Family 572024-02-26T10:08:53Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>{{CuratorApproved}}<br />
* [[Author]]: [[User:Stefan Janecek|Stefan Janecek]]<br />
* [[Responsible Curator]]: [[User:Stefan Janecek|Stefan Janecek]]<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 GH57'''<br />
|-<br />
|'''Clan'''<br />
|GH-T<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" |{{CAZyDBlink}}GH57.html<br />
|}<br />
</div><br />
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<br />
== Substrate specificities ==<br />
[[Glycoside hydrolase]] family 57 was established in 1996 <cite>Henrissat1996</cite> based on the existence of the sequences of two “α-amylases” that were dissimilar to typical family [[GH13]] α-amylases <cite>MacGregor2001</cite>. The two were the heat-stable eubacterial amylase from ''Dictyoglomus thermophilum'' known from 1988 <cite>Fukusumi1988</cite> and the extremely thermostable archaeal amylase from ''Pyrococcus furiosus'' determined in 1993 <cite>Laderman1993a</cite>.<br />
<br />
The family has expanded mainly due to the results of genome sequencing projects. More than a thousand of members are known <cite>Cantarel2009,Lombard2014</cite>, all from prokaryotes (with ~1:4 ratio for Archaea:Bacteria) <cite>Blesak2012</cite>. The enzyme specificities of family GH57 includes α-amylase (EC [{{EClink}}3.2.1.1 3.2.1.1]), α-galactosidase (EC [{{EClink}}3.2.1.22 3.2.1.22]), amylopullulanase (EC [{{EClink}}3.2.1.41 3.2.1.41]), branching enzyme (EC [{{EClink}}2.4.1.18 2.4.1.18]) and 4-α-glucanotransferase (EC [{{EClink}}2.4.1.25 2.4.1.25]).<br />
<br />
An archaeal GH57 amylopullulanase from ''Staphylothermus marinus'' has been described exhibiting also the activity of cyclodextrinase (EC [{{EClink}}3.2.1.54 3.2.1.54]) <cite>Li2013</cite>. Based on a preliminary observation that the PF0870 protein encoded in the ''Pyrococcus furiosus'' genome produced maltose <cite>Comfort2008</cite>, a group of GH57 members with proposed specificity of maltogenic amylase (EC [{{EClink}}3.2.1.133 3.2.1.133]) was predicted <cite>Blesak2013</cite> together with another group of non-specified amylases following the partial characterization of an amylolytic enzyme from an uncultured bacterium <cite>Wang2011</cite>. The maltogenic specificity (or maltose-forming amylase) has already been definitively confirmed by both biochemical <cite>Jung2014,Jeon2014</cite> and structural <cite>Park2014</cite> studies. The family GH57 contains further a group of probably non-enzymatic members, i.e. the so-called α-amylase-like proteins having a substitution in one or both catalytic residues <cite>Janecek2011</cite>.<br />
<br />
It is worth mentioning that the two founding members, i.e. the “α-amylases” from ''Dictyoglomus thermophilum'' and ''Pyrococcus furiosus'' are 4-α-glucanotransferases; the former was proven to have transglycosylating activity <cite>Nakajima2004</cite>, whereas the latter was already known to exhibit also the 4-α-glucanotransferase activity <cite>Laderman1993b</cite>.<br />
<br />
A detailed in silico prediction study has indicated a close relatedness of family GH57 to the family GH119 concerning catalytic domain fold, catalytic machinery and conserved sequence regions <cite>Janecek2012</cite>. This original prediction has recently been updated using the AlphFold-generated structural model of a GH119 representative <cite>Polacek2023</cite> and finally confirmed also experimentally by the biochemical characterization of five GH119 members exhibiting a single α-amylase specificity but distinct product profile <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
A direct evidence for the stereochemical outcome of the enzyme-catalyzed reaction has been presented for the branching enzyme from ''Thermus thermophilus'' <cite>Palomo2011</cite> by the NMR analysis of reaction products. The previous observation of a trapped covalent glycosyl-enzyme intermediate <cite>Imamura2001</cite> was also a strong evidence that the GH57 enzymes operate with [[retaining|retention]] of anomeric configuration through a [[classical Koshland retaining mechanism]] with retention of anomeric configuration. The X-ray structure of the 4-α-glucanotransferase from ''Thermococcus litoralis'' revealed average distances of 6.72 Å and 6.97 Å between the [[catalytic nucleophile]] (Glu123) and [[general acid/base]] (Asp214) in the free and acarbose-bound forms of the enzyme, respectively, which also supports a retaining mechanism for this family <cite>Imamura2003</cite> (see also <cite>Davies1995</cite>).<br />
<br />
Detailed kinetic studies have been performed on several GH57 enzymes, including the 4-α-glucanotransferases from ''Thermococcus litoralis'' <cite>Imamura2001,Imamura2003</cite> and ''Pyrococcus furiosus'' <cite>Tang2006</cite>, amylopullulanases from ''Thermococcus hydrothermalis'' <cite>Zona2004</cite> and ''Pyrococcus furiosus'' <cite>Kang2005</cite>, and branching enzymes from ''Thermococcus kodakaraensis'' <cite>Murakami2006</cite> and ''Thermus thermophilus'' <cite>Palomo2011</cite>.<br />
<br />
== Catalytic Residues ==<br />
The sequences of GH57 members are very diverse. Some sequences are shorter than 400 residues whereas others are longer than 1,500 residues <cite>Janecek2005</cite>. This complicated early efforts to align the GH57 sequences using standard alignment methods. A detailed bioinformatics study by Zona ''et al.'' <cite>Zona2004</cite> focused on all available GH57 sequences at that time and identified five conserved sequence regions. This study used knowledge of the identity of the [[catalytic nucleophile]] (Glu123) in the GH57 4-α-glucanotransferase from ''Thermococcus litoralis'' <cite>Imamura2001</cite> together with the three-dimensional structure <cite>Imamura2003</cite> (PDB ID [{{PDBlink}}1k1w 1k1w]) that revealed the [[general acid/base]] residue (Asp214).<br />
<br />
The [[catalytic nucleophile]] (a glutamate) and [[general acid/base]] (an aspartate) are located in the conserved sequence regions 3 and 4, respectively. In addition to assignments in ''Thermococcus litoralis'' 4-α-glucanotransferase discussed above, these residues were identified in the amylopullulanases from ''Thermococcus hydrothermalis'' <cite>Zona2004</cite> and ''Pyrococcus furiosus'' <cite>Kang2005</cite>. The [[catalytic nucleophile]] was also identified in the α-galactosidase from ''Pyrococcus furiosus'' although no success was achieved in assigning the [[general acid/base]] <cite>vanLieshout2003</cite>. It should be taken into account that some GH57 members, which are only hypothetical enzymes/proteins without any biochemical characterization, may lack one or even both catalytic residues <cite>Zona2004,Janecek2011</cite>.<br />
<br />
Based on the five identified conserved sequence regions, the residues His13, Glu79, Glu216 and Asp354 together with Trp120, Trp221 and Trp357 (''Thermococcus hydrothermalis'' amylopullulanase numbering) were postulated <cite>Zona2004</cite> as important determinants of the individual GH57 enzyme specificities <cite>Janecek2011,Blesak2012,Blesak2013</cite>. Of these, the Trp221 has already been confirmed to contribute to the transglycosylation activity of 4-α-glucanotransferase since the mutant W229H of the enzyme from ''Pyrococcus furiosus'' exhibited markedly decreased transglycosylation activity in comparison with the wild-type counterpart <cite>Tang2006</cite>.<br />
<br />
== Three-dimensional structures ==<br />
The structure of the catalytic domain adopts a (β/α)7-barrel, i.e. the irregular (β/α)8-barrel called a pseudo TIM-barrel. In the case of the ''Thermococcus litoralis'' 4-α-glucanotransferase <cite>Imamura2003</cite> the catalytic domain is succeeded by a C-terminal non-catalytic domain consisting of only β-strands that adopts a twisted β-sandwich fold. In the three-dimensional structure of the α-amylase AmyC from ''Thermotoga maritima'' <cite>Dickmanns2006</cite> (PDB ID [{{PDBlink}}2b5d 2b5d]) (note that the sequence of this enzyme strongly resemles that of a branching enzyme <cite>Blesak2012</cite>), the corresponding catalytic (β/α)7-barrel is followed by a five-helix domain C, a small helical domain B being protruded out of the catalytic pseudo TIM barrel in the place of the loop 2 (i.e. succeeding the strand β2). This structure was found to be closely similar to that of the GH57 member of unknown function from ''Thermus thermophilus'' (PDB ID [{{PDBlink}}1ufa 1ufa]). Two structures of biochemically characterized branching enzymes were solved and published: one from ''Thermus thermophilus'' <cite>Palomo2011</cite> (PDB ID [{{PDBlink}}3p0b 3p0b]) and the other one from ''Thermococcus kodakaraensis'' <cite>Santos2011</cite> (PDB ID [{{PDBlink}}3n8t 3n8t]). The former study <cite>Palomo2011</cite>, importantly, is the first report to prove that a retaining mechanism is employed in the family GH57. Also, the 3-D structure is available for the maltogenic (maltose-forming) amylase from ''Pyrococcus'' sp. ST04 <cite>Park2014</cite> (PDB ID [{{PDBlink}}4cmr 4cmr]). In all cases, the catalytic glutamic acid and aspartic acid residues are located near the C-terminal ends of the strands β4 and β7 of the barrel, respectively <cite>Imamura2003,Dickmanns2006</cite>. There was also a crystallization report in 1995 on a probable GH57 amylopullulanase from ''Pyrococcus woesei'' <cite>Knapp1995</cite>, but the detailed crystallographic analysis of this protein has not been published.<br />
<br />
It is clear that the C-terminal domain cannot be present in some GH57 members with shorter amino acid sequences, e.g., in the α-galactosidases containing less than 400 residues <cite>vanLieshout2003</cite>. On the other hand, some other GH57 members, especially the extra-long amylopullulanases with more than 1,300 residues <cite>Erra-Pujada1999</cite> have to contain even additional domains. One of them could be a longer version of a typical surface layer homology (SLH) motif <cite>Lupas1994</cite> that was named as the so-called SLH motif-bearing domain in the amylopullulanase from ''Thermococcus hydrothermalis'' <cite>Erra-Pujada1999</cite>. This domain was found also in the [[GH15]] glucodextranase from ''Arthrobacter globiformis'' <cite>Mizuno2004</cite>. Remarkably, within the family GH57, the presence of this SLH motif-bearing domain is restricted only for amylopullulanases <cite>Zona2005</cite>.<br />
<br />
It is also worth mentioning that, especially prior the first three-dimensional structure of a GH57 member was available, there were some efforts to join the family GH57 with the main α-amylase family [[GH13]], i.e. the present clan [GH-H] consisting of the families [[GH13]], [[GH70]] and [[GH77]] <cite>MacGregor2001</cite>. Those efforts were focused mainly on looking for some remote homology at the sequence level only <cite>Dong1997,Janecek1998</cite>. Although both GH57 and GH-H employ the same retaining reaction mechanism <cite>Imamura2003,Matsuura1984</cite> the independence of the family GH57 with regard to GH-H clan is at present based not only on differences in the catalytic domain, but more importantly, on the differences in the catalytic machineries and conserved sequence regions <cite>Zona2004,Janecek2002</cite>. As far as other GH families are concerned, the family [[GH38]] α-mannosidase from ''Drosophila melanogaster'' <cite>vandenElsen2001</cite> was revealed to share some structural similarities within the catalytic domain with the GH57 4-α-glucanotransferase from ''Thermococcus litoralis'' <cite>Imamura2001,Imamura2003</cite> indicating an eventuality of originating from a common ancestor.<br />
<br />
== Family Firsts ==<br />
;First sterochemistry determination: The first direct evidence of the retaining reaction stereochemistry by product analysis has been delivered by 1H-NMR analysis of the product mixture that confirmed the α-anomeric configuration of the α-1,6-glucosidic bond formed after the incubation of ''Thermus thermophilus'' branching enzyme with amylose <cite>Palomo2011</cite>. Previously, family GH57 enzymes have been indicated to be retaining by trapping of a covalent glycosyl-enzyme intermediate <cite>Imamura2001</cite> and a 6.7 Å distance between the catalytic nucleophile and acid/base <cite>Imamura2003</cite>, both of which are consistent with a two-step, double-displacement mechanism. <br />
;First amino acid sequence determination: The first amino acid sequence of the family GH57 was that of the heat stable amylase from an anaerobic thermophilic bacterium ''Dictyoglomus thermophilum'' <cite>Fukusumi1988</cite>. This "α-amylase" was later characterized as 4-α-glucanotransferase <cite>Nakajima2004</cite>. In fact, the family contains many α-amylase-like proteins, i.e. those that exhibit a clear sequence homology with α-amylases, but possess a substitution in one or both catalytic residues <cite>Janecek2011</cite>.<br />
;First conserved sequence regions determination: The five sequence stretches characteristic as conserved regions for the family GH57 were first determined by the bioinformatics study by Zona et al. (2004) <cite>Zona2004</cite>.<br />
;First [[catalytic nucleophile]] identification: The catalytic nucleophile was fist identified by Imamura et al. (2001) <cite>Imamura2001</cite> as Glu123 in the 4-α-glucanotransferase from ''Thermococcus litoralis'' using the 3-ketobutylidene-β-2-chloro-4-nitrophenyl maltopentaoside as a donor.<br />
;First [[general acid/base]] residue identification: Asp214 of the 4-α-glucanotransferase from ''Thermococcus litoralis'' as indicated by the X-ray crystallography and supported by site-directed mutagenesis <cite>Imamura2003</cite> since the D214N mutant exhibited a 10,000-fold decrease of specific activity in comparison with the wild-type enzyme.<br />
;First 3-D structure: The first 3-D structure of a GH57 member was that of the 4-α-glucanotransferase from ''Thermococcus litoralis'' <cite>Imamura2003</cite>.<br />
<br />
== References ==<br />
<biblio><br />
#Henrissat1996 pmid=8687420<br />
#MacGregor2001 pmid=11257505<br />
#Fukusumi1988 pmid=2453362<br />
#Laderman1993a pmid=8226990<br />
#Cantarel2009 pmid=18838391<br />
#Lombard2014 pmid=24270786<br />
#Blesak2012 pmid=22527043<br />
#Li2013 pmid=23001056<br />
#Comfort2008 pmid=18156337<br />
#Blesak2013 pmid=24109595<br />
#Wang2011 pmid=21455739<br />
#Jung2014 pmid=23884203<br />
#Jeon2014 pmid=24835094<br />
#Park2014 pmid=24914977<br />
#Janecek2011 pmid=21786160<br />
#Nakajima2004 pmid=15564678<br />
#Laderman1993b pmid=8226989<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A, Janecek S. ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57.'' Biologia 2023; 78(7): 1847-60. [https://doi.org/10.1007/s11756-023-01349-y DOI: 10.1007/s11756-023-01349-y]<br />
#Vuillemin2024 pmid=38280706<br />
#Palomo2011 pmid=21097495<br />
#Imamura2003 pmid=12618437<br />
#Imamura2001 pmid=11591160<br />
#Davies1995 pmid=8535779<br />
#Tang2006 pmid=17035108<br />
#Zona2004 pmid=15233783<br />
#Kang2005 pmid=15599521<br />
#Murakami2006 pmid=16885460<br />
#Janecek2005 Janecek S ''Amylolytic families of glycoside hydrolases: focus on the family GH-57.'' Biologia 2005; 60(Suppl. 16): 177-84. ([http://biologia.savba.sk/Suppl_16/Janecek_S.pdf PDF])<br />
#vanLieshout2003 van Lieshout JFT, Verhees CH, Ettema TJG, van der Saar S, Imamura H, Matsuzawa H, van der Oost J, de Vos WM. ''Identification and molecular characterization of a novel type of α-galactosidase from Pyrococcus furiosus.'' Biocatal Biotransform 2003; 21(4-5): 243-52. [http://dx.doi.org/10.1080/10242420310001614342 DOI: 10.1080/10242420310001614342])<br />
#Dickmanns2006 pmid=16510973<br />
#Santos2011 pmid=21104698<br />
#Knapp1995 pmid=8749857<br />
#Erra-Pujada1999 pmid=10322035<br />
#Lupas1994 pmid=8113161<br />
#Mizuno2004 pmid=14660574<br />
#Zona2005 Zona R, Janecek S. ''Relationships between SLH motifs from different glycoside hydrolase families.'' Biologia 2005; 60(Suppl. 16): 115-21. ([http://biologia.savba.sk/Suppl_16/Zona_R.pdf PDF])<br />
#Dong1997 pmid=9293009<br />
#Janecek1998 pmid=9721603<br />
#Matsuura1984 pmid=6609921<br />
#Janecek2002 Janecek S. ''How many conserved sequence regions are there in the α-amylase family?'' Biologia 2002; 57(Suppl. 11): 29-41. ([http://biologia.savba.sk/Suppl_11/Janecek.pdf PDF])<br />
#vandenElsen2001 pmid=11406577<br />
</biblio><br />
<br />
[[Category:Glycoside Hydrolase Families|GH057]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17937Glycoside Hydrolase Family 1192024-02-26T10:06:55Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>{{CuratorApproved}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-T<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' <cite>Watanabe2006</cite> expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase <cite>Watanabe2006</cite>.<br />
<br />
In the CAZy database, the two largest amylolytic families, [[GH13]] and [[GH57]], are notably multi-specific, with α-amylase representing just one of more than 30 specificities in [[GH13]] <cite>Janecek2022</cite>. Family GH119 was predicted in 2012 <cite>Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family [[GH57]] (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity <cite>Polacek2023</cite>. This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5 <cite>Janecek2011,Blesak2012</cite>.<br />
[[File:GH57 GH119 structure comparison.jpg|thumb|400px|right|'''Figure 1. Original structure comparison of families [[GH57]] and GH119 <cite>Janecek2012</cite>.''' (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' [[GH57]] 4-α-glucanotransferase (red; PDB: [{{PDBlink}}1K1Y 1K1Y]; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in [[GH57]] 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with [[GH57]] 4-α-glucanotransferase is also shown.]]<br />
<br />
Vuillemin ''et al.'' <cite>Vuillemin2024</cite> expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119. They all showed a specificity very similar to that of IgtZ: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' <cite>Watanabe2006</cite> confirmed by polarimetry in 2006. The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57 <cite>Janecek2012,Polacek2023</cite>. Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and [[GH57]] crystallographic structures, it has been shown that GH119 sequences share the same five CSRs typical of [[GH57]] <cite>Janecek2012</cite>. The strictly conserved, catalytic residues of [[GH57]], namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base <cite>Imamura2001,Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity <cite>Vuillemin2024</cite>. Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt the (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices also adopted by [[GH57]] <cite>Janecek2012,Polacek2023</cite>. Based on these differential features, GH119 and [[GH57]] define clan GH-T <cite>Vuillemin2024</cite>.<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, sequence comparisons indicate that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families [[CBM20]], CBM25 and CBM26, fibronectin type III (FN-III) and dockerin domains, among others <cite>Polacek2023, Vuillemin2024,Janecek2019</cite>. A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns <cite>Vuillemin2024</cite>. Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two [[CBM20]] in tandem and a C-terminal CBM25 <cite>Polacek2023</cite>.<br />
[[File:GH119_phylogenetic_tree.jpg|thumb|400px|right|'''Figure 2. Phylogenetic tree representing 52 GH119 representative sequences <cite>Vuillemin2024</cite>.''' Tree branches in the same clade share the same colour. Stars mark experimentally characterized sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name colored by phylum and predicted sequence domain composition.]]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe ''et al.'' <cite>Watanabe2006</cite>, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and [[GH57]] MSAs <cite>Janecek2012,Polacek2023</cite>. The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis <cite>Vuillemin2024</cite>.<br />
;First general acid/base residue identification: As above, also inferred through alignment <cite>Janecek2012,Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119) <cite>#Vuillemin2024</cite>.<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Blesak2012 pmid=22527043<br />
#Vuillemin2024 pmid=38280706<br />
#Imamura2001 pmid=11591160<br />
#Imamura2003 pmid=12618437<br />
#Janecek2019 pmid=31536775<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17899Glycoside Hydrolase Family 1192024-02-12T15:36:51Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>{{CuratorApproved}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' <cite>Watanabe2006</cite> expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase <cite>Watanabe2006</cite>.<br />
<br />
In the CAZy database, the two largest amylolytic families, [[GH13]] and [[GH57]], are notably multi-specific, with α-amylase representing just one of more than 30 specificities in [[GH13]] <cite>Janecek2022</cite>. Family GH119 was predicted in 2012 <cite>Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family [[GH57]] (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity <cite>Polacek2023</cite>. This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5 <cite>Janecek2011,Blesak2012</cite>.<br />
[[File:GH57 GH119 structure comparison.jpg|thumb|400px|right|'''Figure 1. Original structure comparison of families [[GH57]] and GH119<cite>Janecek2012</cite>.''' (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' [[GH57]] 4-α-glucanotransferase (red; PDB: [{{PDBlink}}1K1Y 1K1Y]; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in [[GH57]] 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with [[GH57]] 4-α-glucanotransferase is also shown.]]<br />
<br />
Vuillemin ''et al.'' <cite>Vuillemin2024</cite> expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119. They all showed a specificity very similar to that of IgtZ: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' <cite>Watanabe2006</cite> confirmed by polarimetry in 2006. The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57 <cite>Janecek2012,Polacek2023</cite>. Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and [[GH57]] crystallographic structures, it has been shown that GH119 sequences share the same five CSRs typical of [[GH57]] <cite>Janecek2012</cite>. The strictly conserved, catalytic residues of [[GH57]], namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base <cite>Imamura2001,Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity <cite>Vuillemin2024</cite>. Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt the (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices also adopted by [[GH57]] <cite>Janecek2012,Polacek2023</cite>. Based on these differential features, GH119 and [[GH57]] define clan GH-S <cite>Vuillemin2024</cite>.<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, sequence comparisons indicate that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families [[CBM20]], CBM25 and CBM26, fibronectin type III (FN-III) and dockerin domains, among others <cite>Polacek2023, Vuillemin2024,Janecek2019</cite>. A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns <cite>Vuillemin2024</cite>. Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two [[CBM20]] in tandem and a C-terminal CBM25 <cite>Polacek2023</cite>.<br />
[[File:GH119_phylogenetic_tree.jpg|thumb|400px|right|'''Figure 2. Phylogenetic tree representing 52 GH119 representative sequences <cite>Vuillemin2024</cite>.''' Tree branches in the same clade share the same colour. Stars mark experimentally characterized sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name colored by phylum and predicted sequence domain composition.]]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe ''et al.'' <cite>Watanabe2006</cite>, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and [[GH57]] MSAs <cite>Janecek2012,Polacek2023</cite>. The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis <cite>Vuillemin2024</cite>.<br />
;First general acid/base residue identification: As above, also inferred through alignment <cite>Janecek2012,Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119) <cite>#Vuillemin2024</cite>.<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Blesak2012 pmid=22527043<br />
#Vuillemin2024 pmid=38280706<br />
#Imamura2001 pmid=11591160<br />
#Imamura2003 pmid=12618437<br />
#Janecek2019 pmid=31536775<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17898Glycoside Hydrolase Family 1192024-02-12T15:25:36Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>{{CuratorApproved}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' <cite>Watanabe2006</cite> expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase <cite>Watanabe2006</cite>.<br />
<br />
In the CAZy database, the two largest amylolytic families, [[GH13]] and [[GH57]], are notably multi-specific, with α-amylase representing just one of more than 30 specificities in [[GH13]] <cite>Janecek2022</cite>. Family GH119 was predicted in 2012 <cite>Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family [[GH57]] (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity <cite>Polacek2023</cite>. This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5.<cite>Janecek2011,Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|400px|right|'''Figure 1. Original structure comparison of families [[GH57]] and GH119<cite>Janecek2012</cite>.''' (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' [[GH57]] 4-α-glucanotransferase (red; PDB: [{{PDBlink}}1K1Y 1K1Y]; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in [[GH57]] 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with [[GH57]] 4-α-glucanotransferase is also shown.]]<br />
<br />
Vuillemin ''et al.'' <cite>Vuillemin2024</cite> expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119. They all showed a specificity very similar to that of IgtZ: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' <cite>Watanabe2006</cite> confirmed by polarimetry in 2006. The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57 <cite>Janecek2012,Polacek2023</cite>. Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and [[GH57]] crystallographic structures, it has been shown that GH119 sequences share the same five CSRs typical of [[GH57]] <cite>Janecek2012</cite>. The strictly conserved, catalytic residues of [[GH57]], namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base <cite>Imamura2001,Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity <cite>Vuillemin2024</cite>. Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt the (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices also adopted by [[GH57]] <cite>Janecek2012,Polacek2023</cite>. Based on these differential features, GH119 and [[GH57]] define clan GH-S <cite>Vuillemin2024</cite>.<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, sequence comparisons indicate that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families [[CBM20]], CBM25 and CBM26, fibronectin type III (FN-III) and dockerin domains, among others <cite>Polacek2023, Vuillemin2024,Janecek2019</cite>. A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns <cite>Vuillemin2024</cite>. Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two [[CBM20]] in tandem and a C-terminal CBM25 <cite>Polacek2023</cite>.<br />
[[File:GH119_phylogenetic_tree.jpg|thumb|400px|right|'''Figure 2. Phylogenetic tree representing 52 GH119 representative sequences <cite>Vuillemin2024</cite>.''' Tree branches in the same clade share the same colour. Stars mark experimentally characterized sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name colored by phylum and predicted sequence domain composition.]]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe ''et al.'' <cite>Watanabe2006</cite>, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and [[GH57]] MSAs <cite>Janecek2012,Polacek2023</cite>. The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis <cite>Vuillemin2024</cite>.<br />
;First general acid/base residue identification: As above, also inferred through alignment <cite>Janecek2012,Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119) <cite>#Vuillemin2024</cite>.<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Blesak2012 pmid=22527043<br />
#Vuillemin2024 pmid=38280706<br />
#Imamura2001 pmid=11591160<br />
#Imamura2003 pmid=12618437<br />
#Janecek2019 pmid=31536775<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17897Glycoside Hydrolase Family 1192024-02-12T15:23:04Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>{{CuratorApproved}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' <cite>Watanabe2006</cite> expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase <cite>Watanabe2006</cite>.<br />
<br />
In the CAZy database, the two largest amylolytic families, [[GH13]] and [[GH57]], are notably multi-specific, with α-amylase representing just one of more than 30 specificities in [[GH13]] <cite>Janecek2022</cite>. Family GH119 was predicted in 2012 <cite>Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family [[GH57]] (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity <cite>Polacek2023</cite>. This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5.<cite>Janecek2011,Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|400px|right|'''Figure 1. Original structure comparison of families [[GH57]] and GH119<cite>Janecek2012</cite>.''' (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' [[GH57]] 4-α-glucanotransferase (red; PDB: [{{PDBlink}}1K1Y 1K1Y]; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in [[GH57]] 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with [[GH57]] 4-α-glucanotransferase is also shown.]]<br />
<br />
Vuillemin ''et al.'' <cite>Vuillemin2024</cite> expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119. They all showed a specificity very similar to that of IgtZ: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' <cite>Watanabe2006</cite> confirmed by polarimetry in 2006. The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57 <cite>Janecek2012,Polacek2023</cite>. Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and [[GH57]] crystallographic structures, it has been shown that GH119 sequences share the same five CSRs typical of [[GH57]] <cite>Janecek2012</cite>. The strictly conserved, catalytic residues of [[GH57]], namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base <cite>Imamura2001,Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity <cite>Vuillemin2024</cite>. Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt the (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices also adopted by [[GH57]] <cite>Janecek2012,Polacek2023</cite>. Based on these differential features, GH119 and [[GH57]] define clan GH-S <cite>Vuillemin2024</cite>.<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families [[CBM20]], CBM25 and CBM26, fibronectin type III (FN-III) and dockerin domains, among others <cite>Polacek2023, Vuillemin2024,Janecek2019</cite>. A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns <cite>Vuillemin2024</cite>. Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two [[CBM20]] in tandem and a C-terminal CBM25 <cite>Polacek2023</cite>.<br />
[[File:GH119_phylogenetic_tree.jpg|thumb|400px|right|'''Figure 2. Phylogenetic tree representing 52 GH119 representative sequences <cite>Vuillemin2024</cite>.''' Tree branches in the same clade share the same colour. Stars mark experimentally characterised sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name coloured by phylum and predicted sequence domain composition.]]<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe ''et al.'' <cite>Watanabe2006</cite>, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and [[GH57]] MSAs <cite>Janecek2012,Polacek2023</cite>. The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis <cite>Vuillemin2024</cite>.<br />
;First general acid/base residue identification: As above, also inferred through alignment <cite>Janecek2012,Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119) <cite>#Vuillemin2024</cite>.<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Blesak2012 pmid=22527043<br />
#Vuillemin2024 pmid=38280706<br />
#Imamura2001 pmid=11591160<br />
#Imamura2003 pmid=12618437<br />
#Janecek2019 pmid=31536775<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17894Glycoside Hydrolase Family 1192024-02-11T13:41:05Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' <cite>Watanabe2006</cite> expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase <cite>Watanabe2006</cite>.<br />
<br />
In the CAZy database, the two largest amylolytic families, [[GH13]] and [[GH57]], are notably multi-specific, with α-amylase representing just one of more than 30 specificities in [[GH13]] <cite>Janecek2022</cite>. Family GH119 was predicted in 2012 <cite>Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family [[GH57]] (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity <cite>Polacek2023</cite>. This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families [[GH57]] and GH119 <cite>Janecek2011,Blesak2012</cite>.<br />
[[File:GH57 GH119 structure comparison.jpg|thumb|400px|right|'''Figure 1. Original structure comparison of families [[GH57]] and GH119 from 2012 <cite>Janecek2012</cite>.''' (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' [[GH57]] 4-α-glucanotransferase (red; PDB: [{{PDBlink}}1K1Y 1K1Y]; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in [[GH57]] 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with [[GH57]] 4-α-glucanotransferase is also shown.]]<br />
<br />
Vuillemin ''et al.'' <cite>Vuillemin2024</cite> expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119. They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' <cite>Watanabe2006</cite> confirmed by polarimetry in 2006. The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57 <cite>Janecek2012,Polacek2023</cite>. Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and [[GH57]] crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of [[GH57]] <cite>Janecek2012</cite>. The strictly conserved, catalytic residues of [[GH57]], namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base <cite>Imamura2001,Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity <cite>Vuillemin2024</cite>. Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices <cite>Janecek2012,Polacek2023</cite>.<br />
These characteristics differentiate the amylolytic families [[GH57]] and GH119 from the main α-amylase family, [[GH13]], which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in [[GH70]] and [[GH77]], all of which are members of clan GH-H <cite>Janecek2022</cite>. Based on these differences, GH119 and [[GH57]] define clan GH-S <cite>Vuillemin2024</cite>.<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families [[CBM20]], CBM25 and CBM26, fibronectin type III (FN-III) and dockerin domains, among others <cite>Polacek2023, Vuillemin2024,Janecek2019</cite>. A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns <cite>Vuillemin2024</cite>. Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two [[CBM20]] in tandem and a C-terminal CBM25 <cite>Polacek2023</cite>.<br />
[[File:GH119_phylogenetic_tree.jpg|thumb|400px|right|'''Figure 2. Phylogenetic tree representing 52 GH119 representative sequences <cite>Vuillemin2024</cite>.''' Tree branches in the same clade share the same colour. Stars mark experimentally characterised sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name coloured by phylum and predicted sequence domain composition.]]<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe ''et al.'' <cite>Watanabe2006</cite>, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and [[GH57]] MSAs <cite>Janecek2012,Polacek2023</cite>. The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis <cite>Vuillemin2024</cite>.<br />
;First general acid/base residue identification: As above, also inferred through alignment <cite>Janecek2012,Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119) <cite>#Vuillemin2024</cite>.<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Blesak2012 pmid=22527043<br />
#Vuillemin2024 pmid=38280706<br />
#Imamura2001 pmid=11591160<br />
#Imamura2003 pmid=12618437<br />
#Janecek2019 pmid=31536775<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17893Glycoside Hydrolase Family 1192024-02-11T13:39:56Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' <cite>Watanabe2006</cite> expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase <cite>Watanabe2006</cite>.<br />
<br />
In the CAZy database, the two largest amylolytic families, [[GH13]] and [[GH57]], are notably multi-specific, with α-amylase representing just one of more than 30 specificities in [[GH13]] <cite>Janecek2022</cite>. Family GH119 was predicted in 2012 <cite>Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family [[GH57]] (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity <cite>Polacek2023</cite>. This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families [[GH57]] and GH119 <cite>Janecek2011,Blesak2012</cite>.<br />
[[File:GH57 GH119 structure comparison.jpg|thumb|400px|right|'''Figure 1. Original structure comparison of families [[GH57]] and GH119 from 2012 <cite>Janecek2012</cite>.''' (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' [[GH57]] 4-α-glucanotransferase (red; PDB: [{{PDBlink}}1K1Y 1K1Y]; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in [[GH57]] 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with [[GH57]] 4-α-glucanotransferase is also shown.]]<br />
<br />
Vuillemin ''et al.'' <cite>Vuillemin2024</cite> expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119. They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase <cite>Vuillemin2024</cite>.<br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' <cite>Watanabe2006</cite> confirmed by polarimetry in 2006. The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and [[GH57]] <cite>Janecek2012,Polacek2023</cite>. Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and [[GH57]] crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of [[GH57]] <cite>Janecek2012</cite>. The strictly conserved, catalytic residues of [[GH57]], namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base <cite>Imamura2001,Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity <cite>Vuillemin2024</cite>. Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices <cite>Janecek2012,Polacek2023</cite>.<br />
These characteristics differentiate the amylolytic families [[GH57]] and GH119 from the main α-amylase family, [[GH13]], which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in [[GH70]] and [[GH77]], all of which are members of clan GH-H <cite>Janecek2022</cite>. Based on these differences, GH119 and [[GH57]] define clan GH-S <cite>Vuillemin2024</cite>.<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families [[CBM20]], CBM25 and CBM26, fibronectin type III (FN-III) and dockerin domains, among others <cite>Polacek2023, Vuillemin2024,Janecek2019</cite>. A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns <cite>Vuillemin2024</cite>. Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two [[CBM20]] in tandem and a C-terminal CBM25 <cite>Polacek2023</cite>.<br />
[[File:GH119_phylogenetic_tree.jpg|thumb|400px|right|'''Figure 2. Phylogenetic tree representing 52 GH119 representative sequences <cite>Vuillemin2024</cite>.''' Tree branches in the same clade share the same colour. Stars mark experimentally characterised sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name coloured by phylum and predicted sequence domain composition.]]<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe ''et al.'' <cite>Watanabe2006</cite>, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and [[GH57]] MSAs <cite>Janecek2012,Polacek2023</cite>. The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis <cite>Vuillemin2024</cite>.<br />
;First general acid/base residue identification: As above, also inferred through alignment <cite>Janecek2012,Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119) <cite>#Vuillemin2024</cite>.<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Blesak2012 pmid=22527043<br />
#Vuillemin2024 pmid=38280706<br />
#Imamura2001 pmid=11591160<br />
#Imamura2003 pmid=12618437<br />
#Janecek2019 pmid=31536775<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17877Glycoside Hydrolase Family 1192024-02-09T05:54:03Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janecek2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Polacek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
[[File:GH119_phylogenetic_tree.jpg|thumb|300px|right|'''Figure 2.''' Phylogenetic tree representing 52 GH119 representative sequences. Tree branches in the same clade share the same colour. Stars mark experimentally characterised sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name coloured by phylum and predicted sequence domain composition..<cite>#Vuillemin2024</cite>]]<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:GH119_phylogenetic_tree.jpg&diff=17876File:GH119 phylogenetic tree.jpg2024-02-09T03:42:09Z<p>Eduardo Moreno Prieto: /* Summary */</p>
<hr />
<div>== Summary ==<br />
Maximum likelihood phylogenetic tree inferred from amino acid sequences of catalytic domains from the current family GH119 members in CAZy. Branch numbers indicate bootstrap values from 1000 replicates. Branches of the major clades 1 (green), 2 (red) and 3 (blue) are colored for easy distinction. Stars on the branches represent characterized members from this (red) and previous studies (black). GenBank accession numbers of each protein are indicated at the end of the dotted lines. CocoGH19 accession number is highlighted in red and AquiGH119 and PlbaGH119 that could not be recombinantly produced, are highlighted in grey. Following the GenBank accession numbers are the organism names, color-coded according to taxonomic phyla. The multidomain architecture of the full-length sequences is on the right. Source: Vuillemin et al., 2024 PubMed ID:38280706.</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17875Glycoside Hydrolase Family 1192024-02-09T03:40:40Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janecek2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Polacek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
[[File:GH119_phylogenetic_tree.jpg|thumb|300px|right|'''Figure 2.''' Phylogenetic tree representing 52 GH119 representative sequences. Tree branches in the same clade share the same colour. Stars mark experimentally characterised sequences. The remaining annotations to each branch, from left to right, include: NCBI accession number, source organism name coloured by phylum and predicted sequence domain composition..<cite>#Vuillemin2024</cite>]]<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17874Glycoside Hydrolase Family 1192024-02-09T03:38:18Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janecek2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Polacek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17873Glycoside Hydrolase Family 1192024-02-09T03:36:18Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janecek2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Polacek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17872Glycoside Hydrolase Family 1192024-02-09T03:32:11Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janecek2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Janecek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
<br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17871Glycoside Hydrolase Family 1192024-02-09T03:28:45Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janeček2022</cite> Family GH119 was predicted in 2012<cite>#Janeček2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janeček2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janeček2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janeček2012</cite><cite>#Polaček2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janeček2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janeček2012</cite><cite>#Polaček2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janeček</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janeček2023</cite><cite>#Vuillemin2024</cite><cite>#Janeček2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polaček2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janeček2012</cite><cite>#Polaček2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janeček2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001]<br />
<br />
#Janeček2012 pmid=22819817<br />
#Polaček2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janeček2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janeček2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17870Glycoside Hydrolase Family 1192024-02-09T03:26:45Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janeček2022</cite> Family GH119 was predicted in 2012<cite>#Janeček2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janeček2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.<cite>#Janeček2012</cite>]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janeček2012</cite><cite>#Polaček2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janeček2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janeček2012</cite><cite>#Polaček2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janeček</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janeček2023</cite><cite>#Vuillemin2024</cite><cite>#Janeček2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polaček2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janeček2012</cite><cite>#Polaček2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janeček2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janeček2012 pmid=22819817<br />
#Polaček2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janeček2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janeček2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17869Glycoside Hydrolase Family 1192024-02-09T03:20:04Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
[[File:GH57 GH119 structure comparison.jpg|thumb|300px|right|'''Figure 1.''' Original structure comparison of families GH57 and GH119 from 2012.[3] (a) Catalytic (β/α)<sub>7</sub>-barrel with succeeding α-helical bundle of ''Thermococcus litoralis'' GH57 4-α-glucanotransferase (red; PDB: 1K1Y; residues M1-Q381) superimposed with substantial part of the (β/α)<sub>7</sub>-barrel domain of ''Niallia circulans'' GH119 α-amylase IgtZ (blue; model; residues T121-D429). The rectangle indicates a detailed view on the right. (b) Focus on catalytic residues in GH57 4-α-glucanotransferase (Glu123 and Asp214) and the predicted catalytic machinery in GH119 α-amylase (Glu231 and Asp373). Acarbose occupying subsites -1 through +3 from the complex with GH57 4-α-glucanotransferase is also shown.]]<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:GH119_phylogenetic_tree.jpg&diff=17868File:GH119 phylogenetic tree.jpg2024-02-09T03:16:22Z<p>Eduardo Moreno Prieto: /* Summary */</p>
<hr />
<div>== Summary ==<br />
Maximum likelihood phylogenetic tree inferred from amino acid sequences of catalytic domains from the current family GH119 members in CAZy. Branch numbers indicate bootstrap values from 1000 replicates. Branches of the major clades 1 (green), 2 (red) and 3 (blue) are colored for easy distinction. Stars on the branches represent characterized members from this (red) and previous studies (black). GenBank accession numbers of each protein are indicated at the end of the dotted lines. CocoGH19 accession number is highlighted in red and AquiGH119 and PlbaGH119 that could not be recombinantly produced, are highlighted in grey. Following the GenBank accession numbers are the organism names, color-coded according to taxonomic phyla. The multidomain architecture of the full-length sequences is on the right. Source: Vuillemin et al, 2024 PubMed ID:38280706.</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:GH57_GH119_structure_comparison.jpg&diff=17867File:GH57 GH119 structure comparison.jpg2024-02-09T03:10:01Z<p>Eduardo Moreno Prieto: Structure comparison of families GH57 and GH119. (a) Superimposed Thermococcus litoralis GH57 4-a-glucanotransferase catalytic (b/a)7-barrel with succeeding ahelical segments (red; real structure; PDB code: 1K1Y [18]; residues M1-Q381) with Bacillus circulans GH119 a-amylase substantial part of the (b/a)7-barrel domain (blue; modelled structure; residues T121-D429). The superimposed part covers 228 Ca-atoms with a 0.66 Å root-mean square deviation. The rectangle indicates a detailed view on t...</p>
<hr />
<div>== Summary ==<br />
Structure comparison of families GH57 and GH119. (a) Superimposed Thermococcus litoralis GH57 4-a-glucanotransferase catalytic (b/a)7-barrel with succeeding ahelical segments (red; real structure; PDB code: 1K1Y [18]; residues M1-Q381) with Bacillus circulans GH119 a-amylase substantial part of the (b/a)7-barrel domain (blue; modelled structure; residues T121-D429). The superimposed part covers 228 Ca-atoms with a 0.66 Å root-mean square deviation. The rectangle indicates a detailed view on the right. (b) A close-up focused on the catalytic residues in the structure of GH57 4-a-glucanotransferase (Glu123 and Asp214) and the proposed equivalent residues in the GH119 a-amylase (Glu231 and Asp373). Acarbose occupying subsites 1 through + 3 [40] in complex with GH57 4-a-glucanotransferase is shown. Source: Janeček et al. 2012, PubMed ID:22819817.</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:GH119_phylogenetic_tree.jpg&diff=17866File:GH119 phylogenetic tree.jpg2024-02-08T15:27:49Z<p>Eduardo Moreno Prieto: /* Summary */</p>
<hr />
<div>== Summary ==<br />
Phylogenetic tree of selected sequences representing the diversity of GH119, annotated with taxonomy and modularity</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:GH119_phylogenetic_tree.jpg&diff=17865File:GH119 phylogenetic tree.jpg2024-02-08T15:27:23Z<p>Eduardo Moreno Prieto: Phylogeneic tree of selected sequences representing the diversity of GH119, annotated with taxonomy and modularity</p>
<hr />
<div>== Summary ==<br />
Phylogeneic tree of selected sequences representing the diversity of GH119, annotated with taxonomy and modularity</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17864Glycoside Hydrolase Family 1192024-02-08T14:17:54Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 define clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17863Glycoside Hydrolase Family 1192024-02-08T14:14:15Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric α-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over α-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an α-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with α-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with α-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of α-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic α-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17862Glycoside Hydrolase Family 1192024-02-08T14:11:26Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards α-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17861Glycoside Hydrolase Family 1192024-02-08T14:07:38Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<br />
|-<br />
|'''Clan''' <br />
|GH-S<br />
|-<br />
|'''Mechanism'''<br />
|retaining<br />
|-<br />
|'''Active site residues'''<br />
|known (inferred)<br />
|-<br />
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''<br />
|-<br />
| colspan="2" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček Š and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček Š (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17860Glycoside Hydrolase Family 1192024-02-08T14:05:06Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janeček S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polaček A and Janeček S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17859Glycoside Hydrolase Family 1192024-02-08T14:01:10Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment<cite>#Janecek2012</cite><cite>#Polacek2023</cite> and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Vuillemin2024</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17858Glycoside Hydrolase Family 1192024-02-08T13:59:43Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Polacek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Polacek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Janecek2011</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17857Glycoside Hydrolase Family 1192024-02-08T13:58:35Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.<cite>#Janecek2012</cite><cite>#Janecek2023</cite> Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>#Janecek2012</cite><cite>#Janecek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Janecek2011</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17856Glycoside Hydrolase Family 1192024-02-08T13:56:17Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from ''Niallia circulans'' AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012<cite>#Janecek2012</cite> to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.<cite>Janecek2012</cite><cite>Janecek2023</cite><br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Janecek2011</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17855Glycoside Hydrolase Family 1192024-02-08T13:49:46Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012#Janecek2012 to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.<cite>#Vuillemin2024</cite> They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.<cite>#Vuillemin2024</cite><br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base<cite>#Imamura2001</cite><cite>#Imamura2003</cite> are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.<cite>#Vuillemin2024</cite> Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.<cite>#Vuillemin2024</cite><br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.<cite>Janecek2023</cite><cite>#Vuillemin2024</cite><cite>#Janecek2019</cite> A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.<cite>#Vuillemin2024</cite> Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.<cite>#Vuillemin2024</cite><br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Janecek2011</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
<br />
#Vuillemin2024 pmid=38280706<br />
<br />
#Imamura2001 pmid=11591160<br />
<br />
#Imamura2003 pmid=12618437<br />
<br />
#Cantarel2009 pmid=18838391<br />
<br />
#Janecek2019 pmid=31536775<br />
<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17854Glycoside Hydrolase Family 1192024-02-08T13:37:12Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012#Janecek2012 to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.<cite>#Janecek2011</cite><cite>#Blesak2012</cite><br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Janecek2011</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
<br />
#Blesak2012 pmid=22527043<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17853Glycoside Hydrolase Family 1192024-02-08T13:34:05Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012#Janecek2012 to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).<cite>#Janecek2011</cite><br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
#Janecek2011 pmid=21786160<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17852Glycoside Hydrolase Family 1192024-02-08T13:27:58Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012#Janecek2012 to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.<cite>#Polacek2023</cite> This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.<cite>#Polacek2023</cite><br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17851Glycoside Hydrolase Family 1192024-02-08T13:26:21Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012#Janecek2012 to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.[4] This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.[4]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
<br />
#Polacek2023 Polacek A and Janecek S (2023). ''Sequence-structural features and evolution of the α-amylase family GH119 revealed by the in silico analysis of its relatedness to the family GH57. Biologia''. 78:1847–1860. [https://doi.org/10.1007/s11756-023-01349-y DOI:10.1007/s11756-023-01349-y]<br />
<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17850Glycoside Hydrolase Family 1192024-02-08T13:23:43Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012[3] to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.[4] This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.<cite>#Janecek2012</cite> The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.[4]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Janecek2012 pmid=22819817<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17849Glycoside Hydrolase Family 1192024-02-08T13:20:51Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012[3] to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.[4] This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.[3] The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.[4]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 pmid=17090949<br />
<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17848Glycoside Hydrolase Family 1192024-02-08T13:19:31Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.<cite>Janecek2022</cite> Family GH119 was predicted in 2012[3] to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.[4] This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.[3] The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.<cite>Janecek2022</cite> Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.[4]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 isbn=1347-6947<br />
#Janecek2022 Janecek S and Svensson B (2022) ''How many α-amylase GH families are there in the CAZy database? Amylase''. 6:1–10. [https://doi.org/10.1515/amylase-2022-0001 DOI:10.1515/amylase-2022-0001] <br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17847Glycoside Hydrolase Family 1192024-02-08T12:52:21Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.[2] Family GH119 was predicted in 2012[3] to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.[4] This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.[3] The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.[2] Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.[4]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 isbn=1347-6947<br />
<br />
#Jane<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=Glycoside_Hydrolase_Family_119&diff=17846Glycoside Hydrolase Family 1192024-02-08T12:50:03Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div><!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption --><br />
{{UnderConstruction}}<br />
* [[Author]]: [[User:Eduardo Moreno Prieto|Eduardo Moreno Prieto]]<br />
* [[Responsible Curator]]s: [[User:Stefan Janecek|Stefan Janecek]] and [[User:Bernard Henrissat|Bernard Henrissat]]<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 GH119'''<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" |{{CAZyDBlink}}GH119.html<br />
|}<br />
</div><br />
<!-- This is the end of the table --><br />
<br />
<br />
== Substrate specificities ==<br />
Glycoside hydrolase family 119 (GH119) contains a relatively small number of exclusively bacterial sequences. The first experimentally-characterized member was the amylolytic enzyme IgtZ from Niallia circulans AM7 (formerly ''Bacillus circulans''). Watanabe ''et al.'' expressed IgtZ’s full sequence and assayed it against a range of oligo- and polymeric ⍺-glucans, demonstrating its ability to break down amylose and soluble starch but not pullulan or dextran. <cite>Watanabe2006</cite> This suggests a strict specificity towards ⍺-1,4 over ⍺-1,6-glucan bonds. The enzyme also acts on maltooligosaccharides with a minimum degree of polymerization (DP) of 4 and maltooligosyl trehaloses with maltooligosaccharide portions of at least 4 monosaccharide units. The enzyme hydrolytic action yields primarily disaccharides (maltose or trehalose) accompanied by smaller amounts of glucose and other maltodextrins. The enzyme specificity increases with the DP of the substrate. Based on these findings, the authors categorized IgtZ as an ⍺-amylase.<cite>Watanabe2006</cite><br />
<br />
In the CAZy database, the two largest amylolytic families, GH13 and GH57, are notably multi-specific, with ⍺-amylase representing just one of more than 30 specificities in GH13.[2] Family GH119 was predicted in 2012[3] to share its catalytic domain fold and catalytic machinery with those of the family GH57 (Fig. 1). It had been also predicted that GH119 would be largely mono-specific, with ⍺-amylase being the primary specificity.[4] This was based on the composition of one of its conserved sequence regions (CSRs), specifically CSR-5, which correlates with substrate specificity in families GH57 and GH119.[5,6]<br />
<br />
Vuillemin ''et al.'' expressed recombinantly the core domain of five other GH119 sequences representing the major phylogenetic clades of family GH119.[7] They all showed a very similar specificity as IgtZ’s: activity on glycogen, soluble starch, amylose and maltooligosaccharides with minimum DP5, but not on pullulan or dextran. This result confirmed the ''in silico'' prediction of uniform specificity. Their product profiles were also similar to IgtZ’s, except for that of ⍺-amylase CocoGH119 from ''Corallococcus coralloides'' DSM 2259, which only produced DP2 and DP3 maltooligosaccharides from longer-chain substrates. This suggests that this enzyme is a maltogenic ⍺-amylase.[7]<br />
<br />
== Kinetics and Mechanism ==<br />
<br />
''Niallia circulans'' IgtZ is a retaining enzyme as Watanabe ''et al.'' confirmed by polarimetry in 2006.<cite>Watanabe2006</cite> The authors did not discuss the enzyme’s possible exo- or endo-acting mode of action.<br />
== Catalytic Residues ==<br />
''In silico'' studies have revealed a close phylogenetic relationship between GH families 119 and 57.[3,4] Through multiple sequence alignment (MSA) and superimposition of GH119 homology models and GH57 crystallographic structures, it has been demonstrated that GH119 sequences share the same five CSRs typical of GH57.[3] The strictly conserved, catalytic residues of GH57, namely a strand β4 glutamate serving as nucleophile and a β7 aspartate serving as acid/base[8,9] are located in CSR-3 and CSR-4, respectively. The equivalent residues in CocoGH119 (E225 and D369) have been found to be essential to catalysis by site-directed mutagenesis experiments resulting in complete abolishment of the enzyme’s activity.[7] Furthermore, homology models of GH119 sequences suggest that their putative catalytic domain may adopt a (β/α)<sub>7</sub>-barrel (i.e., an incomplete TIM-barrel) fold followed by a bundle of α-helices.[3,4]<br />
These characteristics differentiate the amylolytic families GH57 and GH119 from the main α-amylase family, GH13, which adopts a (β/α)<sub>8</sub>-barrel fold (i.e., a classical TIM-barrel) and has a Asp-Glu-Asp catalytic triad, as also observed in GH70 and GH77, all of which are members of clan GH-H.[2] Based on these differences, GH119 and GH57 comprise clan GH-S.[7]<br />
== Three-dimensional structures ==<br />
No 3D structure of a GH119 protein has been experimentally established so far. However, domain prediction indicates that several GH119 proteins exhibit a multi-modular architecture consisting of an N-terminal, putatively-catalytic, main domain followed by a variable number of additional domains, including carbohydrate-binding modules (CBM) of families 20, 25 and 26, fibronectin type III (FN-III) and dockerin domains, among others.[4,7,10] A phylogenetic tree of the family annotated with predicted domain architecture (Fig. 2) shows that different branches exhibit distinctive auxiliary domain patterns.[7] Domain prediction for IgtZ suggests that this enzyme comprises an N-terminal, putative catalytic domain, followed by an FN-III, two CBM20 in tandem and a C-terminal CBM25.[4]<br />
<br />
== Family Firsts ==<br />
;First stereochemistry determination:The first evidence of a retaining mechanism within the family was presented by Watanabe and colleagues, who conducted a polarimetry study of the maltooligosaccharide products resulting from the hydrolysis of maltopentaosyl trehalose by IgtZ.<cite>Watanabe2006</cite><br />
;First catalytic nucleophile identification: Inferred to be a strictly conserved, strand β4 glutamate located in the CSR-3 of GH119 and GH57 MSAs.[3,4] The equivalent residue in CocoGH119 (E225) is essential to catalysis as demonstrated through site-directed mutagenesis.[7]<br />
;First general acid/base residue identification: As above, also inferred through alignment[3,4] and confirmed by site-directed mutagenesis to be a fully conserved, β7 aspartate located in CSR-4 of the family (D369 in CocoGH119).[5]<br />
;First 3-D structure: Not yet determined.<br />
<br />
== References ==<br />
<biblio><br />
<br />
#Watanabe2006 issn=1347-6947<br />
<br />
#Jane<br />
#Cantarel2009 pmid=18838391<br />
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [https://doi.org/10.1042/BIO03004026 DOI:10.1042/BIO03004026].<br />
</biblio><br />
<br />
<!-- Do not delete this Category tag --><br />
[[Category:Glycoside Hydrolase Families|GH119]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:In_the_lab.jpg&diff=17845File:In the lab.jpg2024-02-08T11:50:00Z<p>Eduardo Moreno Prieto: /* Summary */</p>
<hr />
<div>== Summary ==<br />
Eduardo Moreno tries to dissolve an insoluble sugar.</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:In_the_lab.jpg&diff=17844File:In the lab.jpg2024-02-08T11:49:49Z<p>Eduardo Moreno Prieto: /* Summary */</p>
<hr />
<div>== Summary ==<br />
Eduardo Moreno tries to dissolve an insoluble sugar-</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17843User:Eduardo Moreno Prieto2024-02-08T11:49:06Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>[[File:In_the_lab.jpg|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of [[GH20]] lacto-''N''-biosidases <cite>Vuillemin2021</cite>.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors [[User:Bernard Henrissat|Bernard Henrissat]] and Anne S. Meyer. His research has resulted in the expansion of families [[GH123]] <cite>MorenoPrieto2023</cite> and [[GH119]] <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
----<br />
<br />
<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493.[https://doi.org/10.3390/app112311493 DOI:10.3390/app112311493]<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
<br />
<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17842User:Eduardo Moreno Prieto2024-02-08T11:43:35Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>[[File:In_the_lab.jpg|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of [[GH20]] lacto-''N''-biosidases <cite>Vuillemin2021</cite>.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors [[User:Bernard Henrissat|Bernard Henrissat]] and Anne S. Meyer. His research has resulted in the expansion of families [[GH123]] <cite>MorenoPrieto2023</cite> and [[GH119]] <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
----<br />
<br />
<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493. DOI:10.3390/app112311493<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
<br />
<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=File:In_the_lab.jpg&diff=17841File:In the lab.jpg2024-02-08T11:41:41Z<p>Eduardo Moreno Prieto: Eduardo Moreno tries to solubilise an insoluble sugar</p>
<hr />
<div>== Summary ==<br />
Eduardo Moreno tries to solubilise an insoluble sugar</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17828User:Eduardo Moreno Prieto2024-02-08T05:54:22Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>[[Image:Blank_user-200px.png|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of [[GH20]] lacto-''N''-biosidases <cite>Vuillemin2021</cite>.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors [[User:Bernard Henrissat|Bernard Henrissat]] and Anne S. Meyer. His research has resulted in the expansion of families [[GH123]] <cite>MorenoPrieto2023</cite> and [[GH119]] <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
----<br />
<br />
<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493. DOI:10.3390/app112311493<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
<br />
<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17826User:Eduardo Moreno Prieto2024-02-08T05:53:08Z<p>Eduardo Moreno Prieto: </p>
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<div>[[Image:Blank_user-200px.png|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of [[GH20]] lacto-N-biosidases <cite>Vuillemin2021</cite>.<br />
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Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors [[User:Bernard Henrissat|Bernard Henrissat]] and Anne S. Meyer. His research has resulted in the expansion of families [[GH123]] <cite>MorenoPrieto2023</cite> and [[GH119]] <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
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<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493. DOI:10.3390/app112311493<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
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<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17824User:Eduardo Moreno Prieto2024-02-08T05:52:32Z<p>Eduardo Moreno Prieto: </p>
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<div>[[Image:Blank_user-200px.png|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of GH20 lacto-N-biosidases <cite>Vuillemin2021</cite>.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors [[User:Bernard Henrissat|Bernard Henrissat]] and Anne S. Meyer. His research has resulted in the expansion of families GH123 <cite>MorenoPrieto2023</cite> and [[GH119]] <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
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<br />
<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493. DOI:10.3390/app112311493<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
<br />
<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17822User:Eduardo Moreno Prieto2024-02-08T04:33:26Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>[[Image:Blank_user-200px.png|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of GH20 lacto-N-biosidases <cite>Vuillemin2021</cite>.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors Bernard Henrissat and Anne S. Meyer. His research has resulted in the expansion of families GH123 <cite>MorenoPrieto2023</cite> and GH119 <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
----<br />
<br />
<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493. DOI:10.3390/app112311493<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
<br />
<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17821User:Eduardo Moreno Prieto2024-02-08T04:32:55Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>[[Image:Blank_user-200px.png|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis and subsequent work as Research Assistant focused on the discovery, characterisation and engineering of GH20 lacto-N-biosidases <cite>Vuillemin2021</cite>.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors Bernard Henrissat and Anne S. Meyer. His research has resulted in the expansion of families GH123 <cite>MorenoPrieto2023</cite> and GH119 <cite>Vuillemin2024</cite> through experimental characterisation of phylogenetically proximal sequences.<br />
----<br />
<br />
<biblio><br />
#Vuillemin2021 Vuillemin M, Holck J, Matwiejuk M, Moreno Prieto ES, Muschiol, J, Molnar-Gabor D, Meyer AS and Zeuner B. (2021) ''Improvement of the Transglycosylation Efficiency of a Lacto-N-Biosidase from Bifidobacterium bifidum by Protein Engineering. Appl. Sci.'' 11:11493. DOI:10.3390/app112311493<br />
#MorenoPrieto2023 pmid=38129294<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
<br />
<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prietohttps://www.cazypedia.org/index.php?title=User:Eduardo_Moreno_Prieto&diff=17820User:Eduardo Moreno Prieto2024-02-07T17:25:25Z<p>Eduardo Moreno Prieto: </p>
<hr />
<div>[[Image:Blank_user-200px.png|200px|right]]<br />
Eduardo Moreno Prieto earned his BSc degree in Biology from the University of La Laguna, Spain. He then gained experience in environmental consultancy and later ventured into the field of communication in Japan and Korea. Returning to his biology roots, he pursued an MSc degree in Bioinformatics at DTU, Denmark. His master's thesis focused on the discovery, characterisation and engineering of GH20 lacto-N-biosidases.<br />
<br />
Currently, he is immersed in his doctoral programme within the Enzyme Discovery group of DTU’s Bioengineering department, under the supervision of Professors Bernard Henrissat and Anne S. Meyer. His research has resulted in the expansion of families GH123 <cite>MorenoPrieto2023</cite> and GH119 through experimental characterisation of phylogenetically proximal sequences.<br />
----<br />
<br />
<biblio><br />
#Vuillemin2021 doi=10.3390/app112311493<br />
<br />
#MorenoPrieto2023 pmid=38129294<br />
<br />
#Vuillemin2024 pmid=38280706<br />
</biblio><br />
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<!-- Do not remove this Category tag --><br />
[[Category:Contributors|Moreno Prieto,Eduardo]]</div>Eduardo Moreno Prieto