Difference between revisions of "Glycoside Hydrolase Family 192"

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Glycoside Hydrolase Family GH192
Clan	GH-S
Mechanism	inverting
Active site residues	not known
CAZy DB link
https://www.cazy.org/GH192.html

Substrate specificities

PgSGL1(H744_1c0224, KEGG) and PgSGL2(H744_2c1936, KEGG) from Photobacterium gaetbulicola and EeSGL1(A0A081KBI6, Uniprot) from Endozoicomonas elysicola were characterized as reported in 2025 [1]. The three enzymes specifically hydrolyze β-1,2-glucan to produce β-1,2-glucooligosaccharides in an endolytic manner [1].

Kinetics and Mechanism

Hydrolysis of β-1,2-glucan by PgSGL1 suggests that the enzyme follows anomer-inverting mechanism [1]. Analysis of the change of the degree of optical rotation during hydrolysis of β-1,2-glucan and after addition of aqueous ammonia. Sharp decrease of the degree of optical rotation by aqueous ammonia is the same pattern as in the case of GH162 β-1,2-glucanase from Talaromyces funiculosus (TfSGL), an anomer-inverting enzyme [2].

Catalytic Residues

E221(EeSGL1) is the putative general acid as this residue is structurally well-superimposed with the general acid (E262) in GH162 TfSGL [1, 2]. E221Q mutant shows drastic decrease in catalytic activity compared to the wild-type enzyme [1]. E221 is also conserved across other GH-S clan families including GH144, GH193, and GH194. This residue is also conserved in GH189, a family related to clan GH-S, as an acid/base catalyst [3]).
Similarly, D149(EeSGL1) is a residue conserved spatially with several β-1,2-glucanases; GH144 (from Chitinophaga pinensis and Xanthomonas campestris pv. campestris) GH193 (from Sanguibacter keddieii), and GH194 (from P. gaetbulicala) [1, 4]. D149N mutant also shows drastically decreased activity against the wild-type enzyme. Mutational analysis alone is insufficient to definitively identify catalytic residues because a reaction mechanism of GH192 is atypical. A plausible substrate binding mode of EeSGL1 can be obtained by superimposed with the complex structure of GH144 β-1,2-glucanase from X. campestris pv. campestris with β-1,2-glucoheptaose. However, no nucleophilic water is observed and no clear pathway for proton transfer from a nucleophilic water to a general base can be traced. It should be noted that the position of D149 (EeSGL1) does not correspond to that of the general base in GH162 TfSGL nor to the nucleophile in GH189 β-1,2-glucanotransferase [1, 2, 3], which suggests a difference in reaction mechanism between these families.

Three-dimensional structures

Fig. 1. Superimposition of EeSGL1(GH192) and XcSGL(GH144) EeSGL1(PDB ID, 8XUJ) and XcSGL(PDB ID, 8XUL) are shown in cyan and green, respectively. Residues labelled in red are the SGL-defining residues. Residues of XcSGL are labelled with Xc. This figure is modified from []

A ligand-free structure of EeSGL1 is available (PDB ID, 8XUJ) [1]. EeSGL1 is composed of a single (α/α)₆-barrel fold. The overall structure and the shape of catalytic pocket of EeSGL1 are similar to those of GH144 β-1,2-glucanases. The two candidate catalytic residues described above are well-superimposed with GH144 β-1,2-glucanases. Based on the similarity, GH192 is classified into clan GH-S, the same clan as GH144. Interestingly, GH162 represents the phylogenetically closest family to GH192, even though they employ different catalytic mechanisms.

Clan GH-S is composed of GH144, GH162, GH192, GH193, and GH194 which are distantly related families. Although GH189 is also a family distantly related to these families, GH189 is excluded from clan GH-S due to the difference in the reaction mechanism (GH189 enzymes follow anomer-retaining mechanism). These distantly related families including GH189 is called SGL clan [1]. The three residues labelled in red in the catalytic pocket (Fig. 1) are conserved within GH144, GH193 and GH194 families. The three conserved residues are considered as residues defining the SGL clan. Among the three residues, the glutamate residue is the candidate general acid described above.

Family Firsts

First stereochemisty determination: A bacterial β-1,2-glucanase from P. gaetbulicola by monitoring the change in optical rotation [1].
First general base residue identification: not known.
First general acid residue identification: not known.
First 3-D structure: A bacterial β-1,2-glucanase from E. elysicola using molecular replacement [1].

References

All Medline abstracts: PubMed

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 <!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption -->
-{{UnderConstruction}}
+{{CuratorApproved}}
 * [[Author]]: [[User:Masahiro Nakajima|Masahiro Nakajima]]
 * [[Responsible Curator]]:  [[User:Masahiro Nakajima|Masahiro Nakajima]]
@@ Line 29: / Line 29: @@
 == Substrate specificities ==
-PgSGL1(H744_1c0224, KEGG) and PgSGL2(H744_2c1936, KEGG) from <i>Photobacterium gaetbulicola</i> and EeSGL1(A0A081KBI6, Uniprot) from <i>Endozoicomonas elysicola</i> are characterized. The three enzymes are specific to β-1,2-glucan among polysaccharides. They hydrolyze β-1,2-glucan endolytically to produce β-1,2-glucooligosaccharides <cite>Nakajima2025</cite>.
+PgSGL1(H744_1c0224, KEGG) and PgSGL2(H744_2c1936, KEGG) from <i>Photobacterium gaetbulicola</i> and EeSGL1(A0A081KBI6, Uniprot) from <i>Endozoicomonas elysicola</i> were characterized as reported in 2025 <cite>Nakajima2025</cite>. The three enzymes specifically hydrolyze β-1,2-glucan to produce β-1,2-glucooligosaccharides in an endolytic manner <cite>Nakajima2025</cite>.
 == Kinetics and Mechanism ==
-PgSGL1 follows anomer-inverting mechanism, which is determined by measuring change of optical rotation during hydrolysis of β-1,2-glucan  <cite>Nakajima2025</cite>.
+Hydrolysis of β-1,2-glucan by PgSGL1 suggests that the enzyme follows anomer-[[inverting]] mechanism <cite>Nakajima2025</cite>. Analysis of the change of the degree of optical rotation during hydrolysis of β-1,2-glucan and after addition of aqueous ammonia. Sharp decrease of the degree of optical rotation by aqueous ammonia is the same pattern as in the case of [[GH162]] β-1,2-glucanase from <i>Talaromyces funiculosus</i> (TfSGL), an anomer-[[inverting]] enzyme <cite>Tanaka2019</cite>.
 == Catalytic Residues ==
-E221(EeSGL1) is the putative general acid as this residue is structurally well-superimposed with the general acid (E262) in [[GH162]] β-1,2-glucanase from <i>Talaromyces funiculosus</i> <cite>#Tanaka2019</cite>. E221Q mutant shows drastic decrease in catalytic activity compared to the wild-type enzyme <cite>Nakajima2025</cite>. E221 is also conserved across other GH-S clan families including [[GH144]], [[GH193]], and [[GH194]]. <br>
+E221(EeSGL1) is the putative general acid as this residue is structurally well-superimposed with the general acid (E262) in [[GH162]] TfSGL <cite>Nakajima2025, Tanaka2019</cite>. E221Q mutant shows drastic decrease in catalytic activity compared to the wild-type enzyme <cite>Nakajima2025</cite>. E221 is also conserved across other GH-S clan families including [[GH144]], [[GH193]], and [[GH194]]. This residue is also conserved in [[GH189]], a family related to clan GH-S, as an acid/base catalyst <cite>Tanaka2024</cite>). <br>
-Similarly, D149 (EeSGL1) is a spatially conserved residue shared with several β-1,2-glucanases; [[GH144]] (from <i>Chitinophaga pinensis</i> and <i>Xanthomonas campestris pv. campestris</i>) [[GH193]] (from <i>Sanguibacter keddieii</i>), and [[GH194]] (from <i>P. gaetbulicala</i>) <cite>#Nakajima2025, #Abe2017</cite>. D149N mutant also shows drastically decreased activity against the wild-type enzyme. Although the D149N mutation significantly diminished enzymatic activity, a clear proton relay pathway directed toward the anomeric carbon at the cleavage site could not be definitively traced based on the current structural data.
+Similarly, D149(EeSGL1) is a residue conserved spatially with several β-1,2-glucanases; [[GH144]] (from <i>Chitinophaga pinensis</i> and <i>Xanthomonas campestris</i> pv. <i>campestris</i>) [[GH193]] (from <i>Sanguibacter keddieii</i>), and [[GH194]] (from <i>P. gaetbulicala</i>) <cite>#Nakajima2025, #Abe2017</cite>. D149N mutant also shows drastically decreased activity against the wild-type enzyme. Mutational analysis alone is insufficient to definitively identify catalytic residues because a reaction mechanism of
+[[GH192]] is atypical. A plausible substrate binding mode of EeSGL1 can be obtained by superimposed with the complex structure of [[GH144]] β-1,2-glucanase from <i>X. campestris</i> pv. <i>campestris</i> with β-1,2-glucoheptaose. However, no nucleophilic water is observed and no clear pathway for proton transfer from a nucleophilic water to a general base can be traced. It should be noted that the position of D149 (EeSGL1) does not correspond to that of the general base in [[GH162]] TfSGL nor to the nucleophile in [[GH189]] β-1,2-glucanotransferase <cite>Tanaka2019, Tanaka2024, Nakajima2025</cite>, which suggests a difference in reaction mechanism between these families.
 == Three-dimensional structures ==
-A ligand-free structure of EeSGL1 is available <cite>Nakajima2025</cite>.
+[[File:GH192 pedia.png|thumb|right|300px|'''Fig. 1. Superimposition of EeSGL1([[GH192]]) and XcSGL([[GH144]])''' EeSGL1(PDB ID, [{{PDBlink}}8XUJ 8XUJ]) and XcSGL(PDB ID, [{{PDBlink}}8XUL 8XUL]) are shown in cyan and green, respectively. Residues labelled in red are the SGL-defining residues. Residues of XcSGL are labelled with Xc. This figure is modified from <cite>Nakajima2025</cite>]]
+A ligand-free structure of EeSGL1 is available (PDB ID, [{{PDBlink}}8XUJ 8XUJ]) <cite>Nakajima2025</cite>. EeSGL1 is composed of a single (α/α)<sub>6</sub>-barrel fold. The overall structure and the shape of catalytic pocket of EeSGL1 are similar to those of [[GH144]] β-1,2-glucanases. The two candidate catalytic residues described above are well-superimposed with [[GH144]] β-1,2-glucanases. Based on the similarity, [[GH192]] is classified into clan GH-S, the same clan as [[GH144]]. Interestingly, [[GH162]] represents the phylogenetically closest family to [[GH192]], even though they employ different catalytic mechanisms. <br><br>
+Clan GH-S is composed of [[GH144]], [[GH162]], [[GH192]], [[GH193]], and [[GH194]] which are distantly related families. Although [[GH189]] is also a family distantly related to these families, [[GH189]] is excluded from clan GH-S due to the difference in the reaction mechanism ([[GH189]] enzymes follow anomer-[[retaining]] mechanism). These distantly related families including [[GH189]] is called '''SGL clan''' <cite>Nakajima2025</cite>. The three residues labelled in red in the catalytic pocket (Fig. 1) are conserved within [[GH144]], [[GH193]] and [[GH194]] families. The three conserved residues are considered as residues defining the SGL clan. Among the three residues, the glutamate residue is the candidate general acid described above.
 == Family Firsts ==
@@ Line 52: / Line 55: @@
 #Nakajima2025 pmid=40411428
 #Tanaka2019 pmid=30926603
+#Tanaka2024 pmid=38300345
 #Abe2017 pmid=28270506
 </biblio>