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Difference between revisions of "Glycoside Hydrolase Family 128"

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* [[Author]]: ^^^Yuichi Sakamoto^^^
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* [[Responsible Curator]]:  ^^^Yuichi Sakamoto^^^
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* [[Author]]: [[User:Yuichi Sakamoto|Yuichi Sakamoto]] and [[User:Camilla Santos|Camilla Santos]]
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* [[Responsible Curator]]:  [[User:Mario Murakami|Mario Murakami]]
 
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|'''Mechanism'''
 
|'''Mechanism'''
|predicted retaining
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|retaining
 
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|'''Active site residues'''
 
|'''Active site residues'''
|predicted
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|known
 
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|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
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== Substrate specificities ==
+
== Substrate specificity and modes of action ==
Family GH128 contains &beta;-1,3-glucanases that cleave &beta;-1,3 linkages in various &beta;-glucans such as lentinan from ''Lentinula edodes'', laminarin from ''Laminaria digitata'', pachyman from ''Poria cocos'', and curdlan from ''Alcaligenes faecalis''. The first GH128 enzyme, GLU1, was cloned from ''L. edodes'' fruiting bodies (shiitake mushroom). GLU1 did not degrade &beta;-1,3-linkages within &beta;-1,3-1,4-glucans such as barley glucan, indicating the enzyme is categorized into EC [{{EClink}}3.2.1.39 3.2.1.39] <cite>Sakamoto2011</cite>.
+
The first GH128 enzyme, GLU1, was cloned from ''Lentinula edodes'' fruiting bodies (shiitake mushroom) <cite>Sakamoto2011</cite>. GLU1 cleaves &beta;-1,3 linkages in various &beta;-glucans such as endogenous ''L. edodes'' lentinan, laminarin from ''Laminaria digitata'', pachyman from ''Poria cocos'', and curdlan from ''Alcaligenes faecalis'', but does not degrade &beta;-1,3-linkages within &beta;-1,3-1,4-glucans such as barley glucan, indicating the enzyme is categorized into EC [{{EClink}}3.2.1.39 3.2.1.39] <cite>Sakamoto2011</cite>. Further work with several GH128 members corroborated that this family is specific for &beta;-1,3-glucans <cite>Santos2020</cite>. Bacterial members from ''Amycolatopsis mediterranei'' (subgroup I)  and ''Pseudomonas viridiflava'' (subgroup II)exhibit endo-&beta;-1,3-glucanase activity and catalytic rates notably higher than those observed for fungal members <cite>Santos2020</cite>. On the other hand, fungal members display diverse modes of action and substrate specificity. The GH128 members from ''Aureobsidium namibiae'' (subgroup VI) and ''Cryptococcus neoformans'' (subgroup V) are exo-&beta;-1,3-glucanases and release trisaccharides and monosaccharides from the reducing ends, respectively. The enzyme from ''Blastomyces gilchristii'' (subgroup III) is also an exo-&beta;-1,3-glucanase; however, it releases trisaccharides from the non-reducing ends of triple-helical &beta;-1,3-glucans. The founder member of the family, GLU1 from ''L. edodes'' (subgroup IV) is an endo-&beta;-1,3-glucanase with an atypical mode of substrate recognition as in the subgroup VI. Intriguingly, some fungal members from this family, such as those from ''Trichoderma gamsii'' and ''C. neoformans'', are devoid of catalytic activity but conserve the capacity to bind short &beta;-1,3-glucooligosaccharides (subgroup VII) <cite>Santos2020</cite>.
 +
 
 +
=== Clustering of GH128 ===
 +
[[Image:Santos_GH128_final.png|thumb|right|250px|Figure 1. Clustering of the GH128 family into seven subgroups. Adapted from <cite>Santos2020</cite>.]]
 +
GH128 was created based on the study of [[User:Yuichi Sakamoto|Yuichi Sakamoto]] and colleagues <cite>Sakamoto2011</cite>. Years later, a group headed by [[User:Mario Murakami|Mario Murakami]] explored the functional and structural diversity of this family <cite>Santos2020</cite>. For this purpose, they employed phylogenetic and Sequence Similarity Network (SSN, <cite>Atkinson2009</cite>) analyses to segregate the family into putative isofunctional subgroups. The SSN analysis resulted in two discrete clusters (subgroups VI and VII) and a third cluster that was further subdivided into five subgroups (I to V) based on SSN alignment scores and evolutionary closeness (Fig. 1). At least one member of each subgroup was biochemically and structurally characterized. Subgroups I and II were found to be predominantly present in bacteria, and the subgroups III to VII are mostly found in fungi. Bacterial enzymes are faster, feature a substrate-interacting "hydrophobic knuckle" (see [[#Three-dimensional structures]]) and attack the &beta;-1,3-glucan in an endo mode of action, which is compatible with their biological functions (nutrition and competition). Fungal &beta;-1,3-glucanases are known to act on remodeling of their own cell walls. Therefore, these enzymes are slower, more diverse in terms of strategies for substrate recognition (flattening mechanism – subgroups IV and VI; and hydrophobic knuckle – subgroups III, V and VII) and modes of action (exo-enzymes – subgroups III, V and VI; endo-enzymes – subgroup IV; and oligosaccharide binding proteins – subgroup VII).
  
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
''L. edodes'' GLU1 catalyzed the hydrolysis of glucans composed of &beta;-1,3-linked main chains, and reaction product analysis indicated that the enzyme had an endo-hydrolytic mode of action. The optimal pH and temperature of the enzyme for laminarin were pH 4 and at 50 °C, respectively. Detailed mechanistic studies on GH128 have not been performed, but three-dimensional structure prediction has indicated that GLU1 is a member of [[Clan]] GH-A. As such, GH128 members are predicted to be [[retaining]] enzymes <cite>Sakamoto2011</cite>.  
+
As indicated by the first study of a GH128 enzyme <cite>Sakamoto2011</cite>, this family is part of [[Clan]] GH-A, thus suggesting that its members operate by a classical Koshland [[retaining]] mechanism.  This prediction was confirmed through <sup>1</sup>H-nuclear magnetic resonance spectroscopy of enzymatic products <cite>Santos2020</cite>.
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
From the sequence alignment of GH128 members, two conserved glutamic acids, E103 and E195 in ''L. edodes'' GLU1, were predicted to be the catalytic residues <cite>Sakamoto2011</cite>.
+
From the sequence alignment of GH128 members, two glutamic acids, E103 and E195 in ''L. edodes'' GLU1, were predicted to be the catalytic residues <cite>Sakamoto2011</cite>. They were further confirmed to be the [[general acid/base]] and the [[catalytic nucleophile]], respectively, by site-directed mutagenesis of the bacterial GH128 member from ''A. mediterranei'' <cite>Santos2020</cite>. These residues are located at the C-terminal ends of the strands &beta;7 and &beta;4 <cite>Santos2020</cite>, as observed for other [[clan]] GH-A families.
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
A three-dimensional structure homology model of ''L. edodes'' GLU1 indicated similarity with several (beta/alpha)<sub>8</sub>-barrel (TIM-barrel) structures, including a [[GH39]] beta-xylosidase and a [[GH5]] beta-mannanase <cite>Sakamoto2011</cite>. Therefore, GH128 has been included in [[Clan]] [http://www.cazy.org/Glycoside-Hydrolases.html GH-A].
+
A three-dimensional homology model of ''L. edodes'' GLU1 indicated similarity with several (&beta;/&alpha;)<sub>8</sub>-barrel (TIM-barrel) structures, including a [[GH39]] &beta;-xylosidase and a [[GH5]] &beta;-mannanase <cite>Sakamoto2011</cite>. The fold resembling an (&beta;/&alpha;)<sub>8</sub>-barrel was further confirmed with the crystal structure determination of 9 members of the family <cite>Santos2020</cite>. However, in all structures, the helix &alpha;2 and the strand &beta;3 are strictly absent <cite>Santos2020</cite>. Moreover, some enzymes such as the endo-&beta;-1,3-glucanase from ''L. edodes'' (GLU1) and the exo-&beta;-1,3-glucanase from ''C. neoformans'', also lack the helices &alpha;1 and &alpha;3, respectively <cite>Santos2020</cite>.
 +
 
 +
Two distinct modes of substrate binding were observed in the GH128 family <cite>Santos2020</cite>. The most widespread mode, termed as "hydrophobic knuckle", involves a tryptophan residue that interacts with four glucoside moieties from –5 to –2 and is fully complementary to the typically curved conformation of &beta;-1,3-glucan chains. The other mode, only observed in fungal members belonging to subgroups IV and VI, requires substrate conformational changes to allow the binding to the catalytic interface. In these fungal subgroups, the hydrophobic knuckle is absent and two aromatic residues, positioned at the -5 and -4 subsites, create a linearized cleft, which requires a 180° torsion in the glycosidic bond between the glycosyl moieties –2 and –3 in the &beta;-1,3-glucan chain for binding. This mode of substrate recognition is referred to as the "flattening" mechanism, due to the unusual, but also stereochemically favorable, conformation adopted by the substrate. It is notable that this mode of substrate binding has not been observed in other CAZy families active on &beta;-1,3-glucans.
  
 
== Family Firsts ==
 
== Family Firsts ==
;First stereochemistry determination: Predicted to be [[retaining]] by membership in [[Clan]] GH-A (not experimentally verified) <cite>Sakamoto2011</cite>.
+
;First stereochemistry determination: predicted to be retaining by membership in Clan GH-A <cite>Sakamoto2011</cite> and further validated by <sup>1</sup>H-NMR analysis of laminarin products generated by the ''A. mediterranei'' endo-&beta;-1,3-glucanase (AmGH128_I) <cite>Santos2020</cite>.
;First catalytic nucleophile identification: Predicted by sequence alignment (not experimentally verified) <cite>Sakamoto2011</cite>.
+
;First catalytic nucleophile identification: predicted by sequence alignment <cite>Sakamoto2011</cite> and confirmed by site-directed mutagenesis of ''A. mediterranei'' endo-&beta;-1,3-glucanase (AmGH128_I) <cite>Santos2020</cite>.
;First general acid/base residue identification: Predicted by sequence alignment (not experimentally verified) <cite>Sakamoto2011</cite>.
+
;First general acid/base residue identification: predicted by sequence alignment <cite>Sakamoto2011</cite> and confirmed by site-directed mutagenesis of ''A. mediterranei'' endo-&beta;-1,3-glucanase (AmGH128_I) <cite>Santos2020</cite>.
;First 3-D structure: Predicted by modelling to be homologous to [[Clan]] GH-A (not experimentally verified) <cite>Sakamoto2011</cite>.
+
;First 3-D structure: predicted by modelling of ''L. edodes'' GLU1 <cite>Sakamoto2011</cite> and experimentally determined for several GH128 members including endo-&beta;-1,3-glucanases from ''A. mediterranei'' (AmGH128_I), ''P. viridiflava'' (PvGH128_II), ''Sorangium cellulosum'' (ScGH128_II) and ''L. edodes'' (LeGH128_IV); exo-&beta;-1,3-glucanases from ''B. gilchristii'' (BgGH128_III), ''C. neoformans'' (CnGH128_V) and ''A. namibiae'' (AnGH128_VI); and &beta;-1,3-glucooligosaccharide binding proteins from ''T. gamsii'' (TgGH128_VII) and ''C. neoformans'' (CnGH128_VII) <cite>Santos2020</cite>.
  
 
== References ==
 
== References ==
 
<biblio>
 
<biblio>
 +
 
#Sakamoto2011 pmid=21965406
 
#Sakamoto2011 pmid=21965406
 +
#Santos2020 pmid=32451508
 +
#Atkinson2009 pmid=19190775
  
 
</biblio>
 
</biblio>

Latest revision as of 13:14, 18 December 2021

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Glycoside Hydrolase Family GH128
Clan GH-A
Mechanism retaining
Active site residues known
CAZy DB link
https://www.cazy.org/GH128.html


Substrate specificity and modes of action

The first GH128 enzyme, GLU1, was cloned from Lentinula edodes fruiting bodies (shiitake mushroom) [1]. GLU1 cleaves β-1,3 linkages in various β-glucans such as endogenous L. edodes lentinan, laminarin from Laminaria digitata, pachyman from Poria cocos, and curdlan from Alcaligenes faecalis, but does not degrade β-1,3-linkages within β-1,3-1,4-glucans such as barley glucan, indicating the enzyme is categorized into EC 3.2.1.39 [1]. Further work with several GH128 members corroborated that this family is specific for β-1,3-glucans [2]. Bacterial members from Amycolatopsis mediterranei (subgroup I) and Pseudomonas viridiflava (subgroup II)exhibit endo-β-1,3-glucanase activity and catalytic rates notably higher than those observed for fungal members [2]. On the other hand, fungal members display diverse modes of action and substrate specificity. The GH128 members from Aureobsidium namibiae (subgroup VI) and Cryptococcus neoformans (subgroup V) are exo-β-1,3-glucanases and release trisaccharides and monosaccharides from the reducing ends, respectively. The enzyme from Blastomyces gilchristii (subgroup III) is also an exo-β-1,3-glucanase; however, it releases trisaccharides from the non-reducing ends of triple-helical β-1,3-glucans. The founder member of the family, GLU1 from L. edodes (subgroup IV) is an endo-β-1,3-glucanase with an atypical mode of substrate recognition as in the subgroup VI. Intriguingly, some fungal members from this family, such as those from Trichoderma gamsii and C. neoformans, are devoid of catalytic activity but conserve the capacity to bind short β-1,3-glucooligosaccharides (subgroup VII) [2].

Clustering of GH128

Figure 1. Clustering of the GH128 family into seven subgroups. Adapted from [2].

GH128 was created based on the study of Yuichi Sakamoto and colleagues [1]. Years later, a group headed by Mario Murakami explored the functional and structural diversity of this family [2]. For this purpose, they employed phylogenetic and Sequence Similarity Network (SSN, [3]) analyses to segregate the family into putative isofunctional subgroups. The SSN analysis resulted in two discrete clusters (subgroups VI and VII) and a third cluster that was further subdivided into five subgroups (I to V) based on SSN alignment scores and evolutionary closeness (Fig. 1). At least one member of each subgroup was biochemically and structurally characterized. Subgroups I and II were found to be predominantly present in bacteria, and the subgroups III to VII are mostly found in fungi. Bacterial enzymes are faster, feature a substrate-interacting "hydrophobic knuckle" (see #Three-dimensional structures) and attack the β-1,3-glucan in an endo mode of action, which is compatible with their biological functions (nutrition and competition). Fungal β-1,3-glucanases are known to act on remodeling of their own cell walls. Therefore, these enzymes are slower, more diverse in terms of strategies for substrate recognition (flattening mechanism – subgroups IV and VI; and hydrophobic knuckle – subgroups III, V and VII) and modes of action (exo-enzymes – subgroups III, V and VI; endo-enzymes – subgroup IV; and oligosaccharide binding proteins – subgroup VII).

Kinetics and Mechanism

As indicated by the first study of a GH128 enzyme [1], this family is part of Clan GH-A, thus suggesting that its members operate by a classical Koshland retaining mechanism. This prediction was confirmed through 1H-nuclear magnetic resonance spectroscopy of enzymatic products [2].

Catalytic Residues

From the sequence alignment of GH128 members, two glutamic acids, E103 and E195 in L. edodes GLU1, were predicted to be the catalytic residues [1]. They were further confirmed to be the general acid/base and the catalytic nucleophile, respectively, by site-directed mutagenesis of the bacterial GH128 member from A. mediterranei [2]. These residues are located at the C-terminal ends of the strands β7 and β4 [2], as observed for other clan GH-A families.

Three-dimensional structures

A three-dimensional homology model of L. edodes GLU1 indicated similarity with several (β/α)8-barrel (TIM-barrel) structures, including a GH39 β-xylosidase and a GH5 β-mannanase [1]. The fold resembling an (β/α)8-barrel was further confirmed with the crystal structure determination of 9 members of the family [2]. However, in all structures, the helix α2 and the strand β3 are strictly absent [2]. Moreover, some enzymes such as the endo-β-1,3-glucanase from L. edodes (GLU1) and the exo-β-1,3-glucanase from C. neoformans, also lack the helices α1 and α3, respectively [2].

Two distinct modes of substrate binding were observed in the GH128 family [2]. The most widespread mode, termed as "hydrophobic knuckle", involves a tryptophan residue that interacts with four glucoside moieties from –5 to –2 and is fully complementary to the typically curved conformation of β-1,3-glucan chains. The other mode, only observed in fungal members belonging to subgroups IV and VI, requires substrate conformational changes to allow the binding to the catalytic interface. In these fungal subgroups, the hydrophobic knuckle is absent and two aromatic residues, positioned at the -5 and -4 subsites, create a linearized cleft, which requires a 180° torsion in the glycosidic bond between the glycosyl moieties –2 and –3 in the β-1,3-glucan chain for binding. This mode of substrate recognition is referred to as the "flattening" mechanism, due to the unusual, but also stereochemically favorable, conformation adopted by the substrate. It is notable that this mode of substrate binding has not been observed in other CAZy families active on β-1,3-glucans.

Family Firsts

First stereochemistry determination
predicted to be retaining by membership in Clan GH-A [1] and further validated by 1H-NMR analysis of laminarin products generated by the A. mediterranei endo-β-1,3-glucanase (AmGH128_I) [2].
First catalytic nucleophile identification
predicted by sequence alignment [1] and confirmed by site-directed mutagenesis of A. mediterranei endo-β-1,3-glucanase (AmGH128_I) [2].
First general acid/base residue identification
predicted by sequence alignment [1] and confirmed by site-directed mutagenesis of A. mediterranei endo-β-1,3-glucanase (AmGH128_I) [2].
First 3-D structure
predicted by modelling of L. edodes GLU1 [1] and experimentally determined for several GH128 members including endo-β-1,3-glucanases from A. mediterranei (AmGH128_I), P. viridiflava (PvGH128_II), Sorangium cellulosum (ScGH128_II) and L. edodes (LeGH128_IV); exo-β-1,3-glucanases from B. gilchristii (BgGH128_III), C. neoformans (CnGH128_V) and A. namibiae (AnGH128_VI); and β-1,3-glucooligosaccharide binding proteins from T. gamsii (TgGH128_VII) and C. neoformans (CnGH128_VII) [2].

References

  1. Sakamoto Y, Nakade K, and Konno N. (2011). Endo-β-1,3-glucanase GLU1, from the fruiting body of Lentinula edodes, belongs to a new glycoside hydrolase family. Appl Environ Microbiol. 2011;77(23):8350-4. DOI:10.1128/AEM.05581-11 | PubMed ID:21965406 [Sakamoto2011]
  2. Santos CR, Costa PACR, Vieira PS, Gonzalez SET, Correa TLR, Lima EA, Mandelli F, Pirolla RAS, Domingues MN, Cabral L, Martins MP, Cordeiro RL, Junior AT, Souza BP, Prates ÉT, Gozzo FC, Persinoti GF, Skaf MS, and Murakami MT. (2020). Structural insights into β-1,3-glucan cleavage by a glycoside hydrolase family. Nat Chem Biol. 2020;16(8):920-929. DOI:10.1038/s41589-020-0554-5 | PubMed ID:32451508 [Santos2020]
  3. Atkinson HJ, Morris JH, Ferrin TE, and Babbitt PC. (2009). Using sequence similarity networks for visualization of relationships across diverse protein superfamilies. PLoS One. 2009;4(2):e4345. DOI:10.1371/journal.pone.0004345 | PubMed ID:19190775 [Atkinson2009]

All Medline abstracts: PubMed