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Difference between revisions of "Glycoside Hydrolase Family 81"

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Primary sequence alignments of GH81 reveal a number of highly conserved residues, including two glutamate residues and one aspartate residue which are located in the active site cleft and likely to serve as catalytic residues <cite>Martin-Cuadrado2008, McGrath2009, Zhou2013</cite>.
 
Primary sequence alignments of GH81 reveal a number of highly conserved residues, including two glutamate residues and one aspartate residue which are located in the active site cleft and likely to serve as catalytic residues <cite>Martin-Cuadrado2008, McGrath2009, Zhou2013</cite>.
  
Mutagenesis experiments, chemical rescue, and examination of the active site architecture and product conformational itinerary of ligand complexes strongly suggest that one of the two glutamic acids (E542 in GH81 from ''Bacillus halodurans'' C-125) acts as the catalytic base by activating an ideally positioned catalytic water, and the aspartic acid (D422 in ''Bh''GH81) acts as the catalytic acid  <cite>McGrath2009, Pluvinage2017, Kumar2018</cite>. While mutagenesis studies show that mutation of the second glutamic acid (E546 in ''Bh''GH81) results in a dramatic reduction in activity  <cite>McGrath2009</cite>, there is conflicting evidence for the role of this residue in catalysis. Pluvinage ''et al''. report that this residue is not correctly positioned to assist in catalysis  <cite>Pluvinage2017</cite>, while Zhou ''et al''. proposes that this residue is the catalytic acid, as the distance between the two glutamic acids is ideal for the inverting mechanism displayed by these enzymes  <cite>Zhou2013</cite>. As such, the exact identity of the catalytic residues for GH81 enzymes remains unclear.
+
Mutagenesis experiments, chemical rescue, and examination of the active site architecture and product conformational itinerary of ligand complexes strongly suggest that one of the two glutamic acids (E542 in GH81 from ''Bacillus halodurans'' C-125) acts as the catalytic base by activating an ideally positioned catalytic water, and the aspartic acid (D422 in ''Bh''GH81) acts as the catalytic acid  <cite>McGrath2009, Pluvinage2017, Kumar2018</cite>. While mutagenesis studies show that mutation of the second glutamic acid (E546 in ''Bh''GH81) results in a dramatic reduction in activity  <cite>McGrath2009</cite>, the role of this residue in catalysis is unclear.
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
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== Family Firsts ==
 
== Family Firsts ==
 
;First stereochemistry determination: &beta;-glucan binding protein (GBP) from soybean (''Glycine max L.'') by <sup>1</sup>H-NMR <cite>Fliegmann2005</cite>.  
 
;First stereochemistry determination: &beta;-glucan binding protein (GBP) from soybean (''Glycine max L.'') by <sup>1</sup>H-NMR <cite>Fliegmann2005</cite>.  
 
+
;First catalytic nucleophile identification: Lam81A from ''Thermobifida fusca'', by site-directed mutagenesis and azide rescue <cite>McGrath2009</cite>.
 +
;First general acid/base residue identification:
 
;First 3-D structure: Lam81A from ''Rhizomucor miehei'' CAU432 <cite>Zhou2013</cite>.  
 
;First 3-D structure: Lam81A from ''Rhizomucor miehei'' CAU432 <cite>Zhou2013</cite>.  
  

Revision as of 08:53, 22 July 2020

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Glycoside Hydrolase Family GH81
Clan none
Mechanism inverting
Active site residues not known
CAZy DB link
https://www.cazy.org/GH81.html


Substrate specificities

GH81 family are endo-β(1,3)-glucanases (EC 3.2.1.39) with diverse physiological roles, such as plant biomass degradation, cell cycling, and enzymatic pathogen defense. They are mostly found in bacteria and fungi, and are particularly abundant in Saccharomyces and Streptomyces species. Activity has been demonstrated on laminarin [1, 2, 3, 4, 5, 6], curdlan [1, 3, 5, 6], and pachyman [2, 5].

Kinetics and Mechanism

GH81 enzymes follow an inverting mechanism, first shown by 1H-NMR during the hydrolysis of laminarin oligosaccharides [7], and laminarin [2], thus operating by a single-displacement mechanism.

Catalytic Residues

Primary sequence alignments of GH81 reveal a number of highly conserved residues, including two glutamate residues and one aspartate residue which are located in the active site cleft and likely to serve as catalytic residues [3, 4, 8].

Mutagenesis experiments, chemical rescue, and examination of the active site architecture and product conformational itinerary of ligand complexes strongly suggest that one of the two glutamic acids (E542 in GH81 from Bacillus halodurans C-125) acts as the catalytic base by activating an ideally positioned catalytic water, and the aspartic acid (D422 in BhGH81) acts as the catalytic acid [5, 6, 8]. While mutagenesis studies show that mutation of the second glutamic acid (E546 in BhGH81) results in a dramatic reduction in activity [8], the role of this residue in catalysis is unclear.

Three-dimensional structures

Figure 1. Structure of Lam81A from Rhizomucor meihei (PDB ID 4K3A). Domain A (blue) and Domain C (green) comprise the core of the enzyme, with domain B (orange) acting as a stabilizer. The proposed catalytic residues are shown as red sticks.

GH81 are multimodular, although the composition of the domains can vary slightly. The first characterized structure, Lam81A from Rhizomucor miehei CAU432, comprises an N-terminal β-sandwich domain (domain A), a small α/β domain (domain B), and a C-terminal (α/α)6 domain (domain C) [4]. Domains A and C form the core of the enzyme, which is likely stabilized by domain B. (Figure 1). This architecture is largely conserved in the GH81 from Bacillus halodurans C-125 (BhGH81) [5], and the cellulosomal GH81 from Clostridium themocellum ATCC 27405 (CtLam81A) [6], however, the C-terminal domain is a CBM56 in BhGH81 and a cellulosomal dockerin in CtLam81A.

GH81 structures are unique among GHs and also differ from other characterized endo-β(1,3)-glucanases in the PDB. As such, GH81 is not classified into any GH clan.

Figure 2. The structure of GH81 from Bacillus halodurans suggests that GH81 are capable of binding helical forms of β-glucan (PDB ID 5T4G). The triple helical structure of curdlan (beige, yellow, cyan) is shown, with the pitch (16Å) and spacing (5.3Å) between strands indicated. Figure from [5].

Spanning domains A and C is a large cleft (10Å deep, 10Å wide, 70Å long), in which the proposed catalytic residues are located. Extensive co-crystallization of BhGH81 in complex with a range of laminarin oligosaccharides provides structural evidence for the ability of this enzyme for to generate a pool of oligosaccharide products [5]. Notably, these structures clearly define catalytic and ancillary binding subsites, and reveal the ability of this enzyme to simultaneously bind oligosaccharides in these sites, proposing that GH81 bind and cleave helical forms of β-1,3-glucans in an endo-processive manner [5] (Figure 2).

Family Firsts

First stereochemistry determination
β-glucan binding protein (GBP) from soybean (Glycine max L.) by 1H-NMR [7].
First catalytic nucleophile identification
Lam81A from Thermobifida fusca, by site-directed mutagenesis and azide rescue [8].
First general acid/base residue identification
First 3-D structure
Lam81A from Rhizomucor miehei CAU432 [4].

References

  1. Fontaine T, Hartland RP, Beauvais A, Diaquin M, and Latge JP. (1997). Purification and characterization of an endo-1,3-beta-glucanase from Aspergillus fumigatus. Eur J Biochem. 1997;243(1-2):315-21. DOI:10.1111/j.1432-1033.1997.0315a.x | PubMed ID:9030754 [Fontaine1997]
  2. McGrath CE and Wilson DB. (2006). Characterization of a Thermobifida fusca beta-1,3-glucanase (Lam81A) with a potential role in plant biomass degradation. Biochemistry. 2006;45(47):14094-100. DOI:10.1021/bi061757r | PubMed ID:17115704 [McGrath2006]
  3. Martín-Cuadrado AB, Fontaine T, Esteban PF, del Dedo JE, de Medina-Redondo M, del Rey F, Latgé JP, and de Aldana CR. (2008). Characterization of the endo-beta-1,3-glucanase activity of S. cerevisiae Eng2 and other members of the GH81 family. Fungal Genet Biol. 2008;45(4):542-53. DOI:10.1016/j.fgb.2007.09.001 | PubMed ID:17933563 [Martin-Cuadrado2008]
  4. Zhou P, Chen Z, Yan Q, Yang S, Hilgenfeld R, and Jiang Z. (2013). The structure of a glycoside hydrolase family 81 endo-β-1,3-glucanase. Acta Crystallogr D Biol Crystallogr. 2013;69(Pt 10):2027-38. DOI:10.1107/S090744491301799X | PubMed ID:24100321 [Zhou2013]
  5. Pluvinage B, Fillo A, Massel P, and Boraston AB. (2017). Structural Analysis of a Family 81 Glycoside Hydrolase Implicates Its Recognition of β-1,3-Glucan Quaternary Structure. Structure. 2017;25(9):1348-1359.e3. DOI:10.1016/j.str.2017.06.019 | PubMed ID:28781080 [Pluvinage2017]
  6. Kumar K, Correia MAS, Pires VMR, Dhillon A, Sharma K, Rajulapati V, Fontes CMGA, Carvalho AL, and Goyal A. (2018). Novel insights into the degradation of β-1,3-glucans by the cellulosome of Clostridium thermocellum revealed by structure and function studies of a family 81 glycoside hydrolase. Int J Biol Macromol. 2018;117:890-901. DOI:10.1016/j.ijbiomac.2018.06.003 | PubMed ID:29870811 [Kumar2018]
  7. Fliegmann J, Montel E, Djulić A, Cottaz S, Driguez H, and Ebel J. (2005). Catalytic properties of the bifunctional soybean beta-glucan-binding protein, a member of family 81 glycoside hydrolases. FEBS Lett. 2005;579(29):6647-52. DOI:10.1016/j.febslet.2005.10.060 | PubMed ID:16297387 [Fliegmann2005]
  8. McGrath CE, Vuong TV, and Wilson DB. (2009). Site-directed mutagenesis to probe catalysis by a Thermobifida fusca beta-1,3-glucanase (Lam81A). Protein Eng Des Sel. 2009;22(6):375-82. DOI:10.1093/protein/gzp015 | PubMed ID:19435780 [McGrath2009]

All Medline abstracts: PubMed