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Difference between revisions of "Glycoside Hydrolase Family 162"

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* [[Author]]: ^^^Nobukiyo Tanaka^^^
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* [[Author]]: [[User:Nobukiyo Tanaka|Nobukiyo Tanaka]]
* [[Responsible Curator]]:  ^^^Masahiro Nakajima^^^
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* [[Responsible Curator]]:  [[User:Masahiro Nakajima|Masahiro Nakajima]]
 
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|'''Clan'''     
 
|'''Clan'''     
|GH-x
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|Clan-S
 
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|'''Mechanism'''
 
|'''Mechanism'''
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== Substrate specificities ==
 
== Substrate specificities ==
In this [[Glycoside hydrolase]] family 162, the only β-1,2-glucanase from ''Talaromyces funiculosus'' (''Tf''SGL) has been identified, characterized and structurally analyzed to date (5/27/2019) <cite>Tanaka2019</cite>. The enzyme specifically hydrolyzes both cyclic and linear β-1,2-glucans, which comprise a β-linked glucosyl backbone, and preferably releases sophorose (Glc-β-1,2-Glc) from the reducing end of linear β-1,2-glucan <cite>Tanaka2019</cite>. Almost all of the family members are from Eukaryotes <cite>Tanaka2019</cite>.
+
[[Image:The_phylogenetic_tree_of_GH162_homologs.png|thumb|500px|'''Figure 1. The phylogenetic tree of GH162 homologs.''' ]]
[[Image:filename|thumb|widthpx| ]]
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The defining member of [[glycoside hydrolase]] family 162, a β-1,2-glucanase from ''Talaromyces funiculosus'' (''Tf''SGL), was identified, characterized, and structurally analyzed as reported in 2019 <cite>Tanaka2019</cite>. This enzyme specifically hydrolyzes both cyclic and linear β-1,2-glucans, which comprise a β-linked glucosyl backbone, and preferably releases sophorose (Glc-β-1,2-Glc) from the reducing end of linear β-1,2-glucan <cite>Tanaka2019</cite>. Almost all of the family members are from Eukaryotes <cite>Tanaka2019</cite>
  
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
The analysis of action patterns on cyclic β-1,2-glucan reveal that ''Tf''SGL is an ''endo''-type <cite>Tanaka2019</cite>. The NMR analysis of the anomeric configurations of hydrolysates indicated that ''Tf''SGL has an inverting mechanism. In addition, the analysis of the change of the degree of optical rotation during the hydrolysis of β-1,2-glucan also supported this mechanism <cite>Tanaka2019</cite>.
+
[[Image:Catalytic_mechanism_of_Tfsgl.jpeg|thumb|right|350px|'''Figure 2. Active site and reaction mechanism.''' '''(A)''' The complex of the E262Q mutant with β-1,2-glucoheptaose. The numbers beside the substrate represent the positions of subsites. The ''red'' and ''blue'' dotted lines represent the hydrogen bonds between the ligands and D177 or E262, respectively. The β-1,2-glucotriose moiety in the observed substrate is represented by a ''yellow stick''. Candidate residues for a general acid are represented by ''brown sticks''. The 262th glutamine residue is represented as a glutamic acid. '''(B)''' E262 (general acid) indirectly protonates the glycosidic bond oxygen atom via the 3-hydroxy group of the Glc moiety at subsite +2 and D446 (general base) activates the nucleophilic water via another water <cite>Tanaka2019</cite>.]]
According to the structural analysis (see “Three-dimensional structures”), mutational analysis, D446 (general base) activates the nucleophilic water via another water <cite>Tanaka2019</cite>. Furthermore, it is predicted that D177 and/or E262 act as a general acid via the 3-hydroxy groups of the Glc moieties (see below) <cite>Tanaka2019</cite>. The result of the action pattern analysis of β-1,2-sophoropentaose derivatives, deoxygenated at their 3-hydroxy groups at the first or second Glc moiety from the reducing end, indicating that E262 act as a general acid via the 3-hydroxy group of the Glc moiety at subsite +2 <cite>Tanaka2019</cite>. The reaction mechanism of ''Tf''SGL is quite unique in that both reaction pathways involving a general acid and a general base <cite>Tanaka2019</cite>.
+
Hydrolysis of cyclic β-1,2-glucan by ''Tf''SGL suggests that the enzyme is ''endo''-acting <cite>Tanaka2019</cite>. The <sup>1</sup>H-NMR analysis of the anomeric configurations of hydrolysates indicates that ''Tf''SGL has an [[inverting]] mechanism. Analysis of the change of the degree of optical rotation during hydrolysis of β-1,2-glucan also supported this mechanism <cite>Tanaka2019</cite>.
 +
 
 +
Structural analysis (see “Three-dimensional structures” below) and mutational analysis suggest that D446 activates the nucleophilic water via another water as a general acid <cite>Tanaka2019</cite>. These analyses also suggest that D177 and/or E262 act as a general acid via the 3-hydroxy groups of the Glc moieties (see below) <cite>Tanaka2019</cite>. According to action-pattern analysis using β-1,2-glucopentaose derivatives deoxygenated at their 3-hydroxy groups in the first or second Glc moiety from the reducing end, E262 was clearly determined to be a general acid. The 3-hydroxy group of the Glc moiety at subsite +2 mediates protonation of glycosidic bond oxygen atom <cite>Tanaka2019</cite>. The reaction mechanism of ''Tf''SGL is quite unique in that both reaction pathways involving a general acid and a general base are non-canonical <cite>Tanaka2019</cite>.
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
The general acid and base of ''Tf''SGL are E262 and D446, respectively <cite>Tanaka2019</cite>. Both residues are highly conserved in [[GH162]] enzymes. The general acid of ''Tf''SGL is well superimposed with an acidic residue in a [[GH144]] bacterial β-1,2-glucanase from ''Chitinophaga pinensis'' (''Cp''SGL), whereas the general base is not superimposed <cite>Tanaka2019, Abe2017</cite>. Although the reaction mechanisms of GH144 are unclear, ''Tf''SGL is clearly different from [[GH144]] in the reaction mechanism based on structural comparison <cite>Tanaka2019</cite>.
+
The general acid and base of ''Tf''SGL are E262 and D446, respectively <cite>Tanaka2019</cite>. Both residues are highly conserved in [[GH162]] enzymes. The general acid of ''Tf''SGL is well superimposed with an acidic residue in a [[GH144]] bacterial β-1,2-glucanase from ''Chitinophaga pinensis'' (''Cp''SGL), whereas the general base is not superimposed <cite>Tanaka2019, Abe2017</cite>. Although the reaction mechanisms of [[GH144]] enzymes are currently unclear (June 2019), structural comparison of ''Tf''SGL and [[GH144]] suggests differences in reaction mechanisms <cite>Tanaka2019</cite>.
 +
 
 +
A structural comparison revealed that the position of the general acid residue in [[GH162]] and the candidate catalytic residue in [[GH144]] are well superimposed structurally <cite>Tanaka2024</cite>. In contrast, the positions of the other catalytic residues (or candidate catalytic residues) in [[GH162]] and [[GH144]] are completely different <cite>Tanaka2024</cite>. Furthermore, compared to clans GH-G, L, M, O, P and Q, which have the same overall structure (= (α/α)<sub>6</sub> fold) as [[GH162]] and [[GH144]], none of the positions of the catalytic residues in [[GH162]] and [[GH144]] are conserved <cite>Tanaka2024</cite>. A new clan GH-S was created for GH162 and GH144 based on these results <cite>Tanaka2024</cite>.
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
The apo-structure of the recombinant ''Tf''SGL (''Tf''SGLr) was determined at 2.0 Å using the iodide single-wavelength anomalous diffraction phasing method (PDB 6IMU) <cite>Tanaka2019</cite>. The overall structure comprises an (α/α)<sub>6</sub> toroid fold <cite>Tanaka2019</cite>. The complex structure with sophorose (PDB 6IMV) and the Michaelis complex of an inactive ''Tf''SGLr-mutant (E262Q) with a β-1,2-glucoheptasaccharide (PDB 6IMW) were also determined by soaking of crystals in sophorose and β-1,2-glucan, respectively <cite>Tanaka2019</cite>. ''Tf''SGLr has a cleft crossing the surface of the structure and there is a large active pocket at the center of the cleft <cite>Tanaka2019</cite>. Interestingly, although ''Tf''SGL and GH144 enzymes are quite different in their amino acid sequences, their overall structures and the shapes of their active pocket are similar <cite>Tanaka2019</cite>. ''Tf''SGLr has slight structural similarity to [[GH15]] and [[GH8]] enzymes.
+
[[Image:Overall_structure.jpg|thumb|350px|'''Figure 3. Overall structure of ''Tf''SGL (PDB [{{PDBlink}}6IMU 6IMU]).''' ]]
 +
The apo-structure of the recombinant ''Tf''SGL (''Tf''SGLr) was determined at 2.0 Å using the iodide single-wavelength anomalous diffraction phasing method (PDB [{{PDBlink}}6IMU 6IMU]) <cite>Tanaka2019</cite>. The overall structure comprises an (α/α)<sub>6</sub> toroid fold <cite>Tanaka2019</cite>. The complex structures with sophorose (PDB [{{PDBlink}}6IMV 6IMV]) and the Michaelis complex of an inactive ''Tf''SGLr-mutant (E262Q) with a β-1,2-glucoheptaose (PDB [{{PDBlink}}6IMW 6IMW]) were also determined by soaking of crystals in sophorose and β-1,2-glucan, respectively <cite>Tanaka2019</cite>. ''Tf''SGLr has a cleft crossing the surface of the structure and there is a large active-site pocket at the center of the cleft <cite>Tanaka2019</cite>. Interestingly, although ''Tf''SGL and [[GH144]] enzymes are quite different in their amino acid sequences, their overall structures and the positions of the substrates in their catalytic pockets are similar <cite>Tanaka2019</cite>. ''Tf''SGLr has slight structural similarity to [[GH15]] and [[GH8]] enzymes.
  
 
== Family Firsts ==
 
== Family Firsts ==
 
;First stereochemistry determination: A fungal β-1,2-glucanase from ''Talaromyces funiculosus'' by the NMR analysis and the analysis of the change of the degree of optical rotation <cite>Tanaka2019</cite>.
 
;First stereochemistry determination: A fungal β-1,2-glucanase from ''Talaromyces funiculosus'' by the NMR analysis and the analysis of the change of the degree of optical rotation <cite>Tanaka2019</cite>.
 
 
;First general acid residue identification: A fungal β-1,2-glucanase from ''Talaromyces funiculosus'' by the structural analysis, the mutational analysis and the action pattern analysis of β-1,2-sophoropentaose derivatives <cite>Tanaka2019</cite>.
 
;First general acid residue identification: A fungal β-1,2-glucanase from ''Talaromyces funiculosus'' by the structural analysis, the mutational analysis and the action pattern analysis of β-1,2-sophoropentaose derivatives <cite>Tanaka2019</cite>.
 
;First general base residue identification: A fungal β-1,2-glucanase from ''Talaromyces funiculosus'' by the structural analysis and the mutational analysis <cite>Tanaka2019</cite>.
 
;First general base residue identification: A fungal β-1,2-glucanase from ''Talaromyces funiculosus'' by the structural analysis and the mutational analysis <cite>Tanaka2019</cite>.
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#Tanaka2019 pmid=30926603
 
#Tanaka2019 pmid=30926603
 
#Abe2017 pmid=28270506
 
#Abe2017 pmid=28270506
 +
#Tanaka2024 pmid=38300345
 
</biblio>
 
</biblio>
  

Latest revision as of 19:03, 1 February 2024

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Glycoside Hydrolase Family GH162
Clan Clan-S
Mechanism Inverting
Active site residues Known
CAZy DB link
https://www.cazy.org/GH162.html


Substrate specificities

Figure 1. The phylogenetic tree of GH162 homologs.

The defining member of glycoside hydrolase family 162, a β-1,2-glucanase from Talaromyces funiculosus (TfSGL), was identified, characterized, and structurally analyzed as reported in 2019 [1]. This enzyme specifically hydrolyzes both cyclic and linear β-1,2-glucans, which comprise a β-linked glucosyl backbone, and preferably releases sophorose (Glc-β-1,2-Glc) from the reducing end of linear β-1,2-glucan [1]. Almost all of the family members are from Eukaryotes [1]

Kinetics and Mechanism

Figure 2. Active site and reaction mechanism. (A) The complex of the E262Q mutant with β-1,2-glucoheptaose. The numbers beside the substrate represent the positions of subsites. The red and blue dotted lines represent the hydrogen bonds between the ligands and D177 or E262, respectively. The β-1,2-glucotriose moiety in the observed substrate is represented by a yellow stick. Candidate residues for a general acid are represented by brown sticks. The 262th glutamine residue is represented as a glutamic acid. (B) E262 (general acid) indirectly protonates the glycosidic bond oxygen atom via the 3-hydroxy group of the Glc moiety at subsite +2 and D446 (general base) activates the nucleophilic water via another water [1].

Hydrolysis of cyclic β-1,2-glucan by TfSGL suggests that the enzyme is endo-acting [1]. The 1H-NMR analysis of the anomeric configurations of hydrolysates indicates that TfSGL has an inverting mechanism. Analysis of the change of the degree of optical rotation during hydrolysis of β-1,2-glucan also supported this mechanism [1].

Structural analysis (see “Three-dimensional structures” below) and mutational analysis suggest that D446 activates the nucleophilic water via another water as a general acid [1]. These analyses also suggest that D177 and/or E262 act as a general acid via the 3-hydroxy groups of the Glc moieties (see below) [1]. According to action-pattern analysis using β-1,2-glucopentaose derivatives deoxygenated at their 3-hydroxy groups in the first or second Glc moiety from the reducing end, E262 was clearly determined to be a general acid. The 3-hydroxy group of the Glc moiety at subsite +2 mediates protonation of glycosidic bond oxygen atom [1]. The reaction mechanism of TfSGL is quite unique in that both reaction pathways involving a general acid and a general base are non-canonical [1].

Catalytic Residues

The general acid and base of TfSGL are E262 and D446, respectively [1]. Both residues are highly conserved in GH162 enzymes. The general acid of TfSGL is well superimposed with an acidic residue in a GH144 bacterial β-1,2-glucanase from Chitinophaga pinensis (CpSGL), whereas the general base is not superimposed [1, 2]. Although the reaction mechanisms of GH144 enzymes are currently unclear (June 2019), structural comparison of TfSGL and GH144 suggests differences in reaction mechanisms [1].

A structural comparison revealed that the position of the general acid residue in GH162 and the candidate catalytic residue in GH144 are well superimposed structurally [3]. In contrast, the positions of the other catalytic residues (or candidate catalytic residues) in GH162 and GH144 are completely different [3]. Furthermore, compared to clans GH-G, L, M, O, P and Q, which have the same overall structure (= (α/α)6 fold) as GH162 and GH144, none of the positions of the catalytic residues in GH162 and GH144 are conserved [3]. A new clan GH-S was created for GH162 and GH144 based on these results [3].

Three-dimensional structures

Figure 3. Overall structure of TfSGL (PDB 6IMU).

The apo-structure of the recombinant TfSGL (TfSGLr) was determined at 2.0 Å using the iodide single-wavelength anomalous diffraction phasing method (PDB 6IMU) [1]. The overall structure comprises an (α/α)6 toroid fold [1]. The complex structures with sophorose (PDB 6IMV) and the Michaelis complex of an inactive TfSGLr-mutant (E262Q) with a β-1,2-glucoheptaose (PDB 6IMW) were also determined by soaking of crystals in sophorose and β-1,2-glucan, respectively [1]. TfSGLr has a cleft crossing the surface of the structure and there is a large active-site pocket at the center of the cleft [1]. Interestingly, although TfSGL and GH144 enzymes are quite different in their amino acid sequences, their overall structures and the positions of the substrates in their catalytic pockets are similar [1]. TfSGLr has slight structural similarity to GH15 and GH8 enzymes.

Family Firsts

First stereochemistry determination
A fungal β-1,2-glucanase from Talaromyces funiculosus by the NMR analysis and the analysis of the change of the degree of optical rotation [1].
First general acid residue identification
A fungal β-1,2-glucanase from Talaromyces funiculosus by the structural analysis, the mutational analysis and the action pattern analysis of β-1,2-sophoropentaose derivatives [1].
First general base residue identification
A fungal β-1,2-glucanase from Talaromyces funiculosus by the structural analysis and the mutational analysis [1].
First 3-D structure
A fungal β-1,2-glucanase from Talaromyces funiculosus using the iodide single-wavelength anomalous diffraction phasing method [1].

References

  1. Tanaka N, Nakajima M, Narukawa-Nara M, Matsunaga H, Kamisuki S, Aramasa H, Takahashi Y, Sugimoto N, Abe K, Terada T, Miyanaga A, Yamashita T, Sugawara F, Kamakura T, Komba S, Nakai H, and Taguchi H. (2019). Identification, characterization, and structural analyses of a fungal endo-β-1,2-glucanase reveal a new glycoside hydrolase family. J Biol Chem. 2019;294(19):7942-7965. DOI:10.1074/jbc.RA118.007087 | PubMed ID:30926603 [Tanaka2019]
  2. Abe K, Nakajima M, Yamashita T, Matsunaga H, Kamisuki S, Nihira T, Takahashi Y, Sugimoto N, Miyanaga A, Nakai H, Arakawa T, Fushinobu S, and Taguchi H. (2017). Biochemical and structural analyses of a bacterial endo-β-1,2-glucanase reveal a new glycoside hydrolase family. J Biol Chem. 2017;292(18):7487-7506. DOI:10.1074/jbc.M116.762724 | PubMed ID:28270506 [Abe2017]
  3. Tanaka N, Saito R, Kobayashi K, Nakai H, Kamo S, Kuramochi K, Taguchi H, Nakajima M, and Masaike T. (2024). Functional and structural analysis of a cyclization domain in a cyclic β-1,2-glucan synthase. Appl Microbiol Biotechnol. 2024;108(1):187. DOI:10.1007/s00253-024-13013-9 | PubMed ID:38300345 [Tanaka2024]

All Medline abstracts: PubMed