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Difference between revisions of "Glycoside Hydrolase Family 36"

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|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
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| colspan="2" |http://www.cazy.org/fam/GH36.html
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== Substrate specificities ==
 
== Substrate specificities ==
Alpha-galactosidase and alpha-N-acetylgalactosaminidase activity has been demonstrated in archaeal, bacterial, and eukaryotic members of this family.  Additionally, certain plant members of this family possess stachyose synthase or raffinose synthase activity.
+
[[Glycoside hydrolases]] of family 36 exhibit &alpha;-galactosidase and &alpha;-''N''-acetylgalactosaminidase activity, which has been demonstrated in archaeal, bacterial, and eukaryotic members of this family.  Additionally, certain plant members of this family possess stachyose synthase or raffinose synthase activity.
  
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
Family GH36 alpha-galactosidases are anomeric configuration-retaining enzymes, as first shown by NMR studies on the alpha-galactosidase GalA from ''Thermotoga maritima'' <cite>1</cite>.  Correspondingly, GH36 enzymes use a classical Koshland double-displacement mechanism <cite>4</cite>, like their [[Glycoside Hydrolase Family GH27 (GH27)]] relatives in Clan GH-D.  This mechanism involves the formation of a covalent glycosyl-enzyme intermediate <cite>5</cite> that partitions predominantly to water in hydrolytic enzymes and to saccharide acceptor substrates in transglycosylating enzymes, such as stachyose and raffinose synthases.
+
Family GH36 &alpha;-galactosidases are anomeric configuration-[[retaining]] enzymes, as first shown by NMR studies on the &alpha;-galactosidase GalA from ''Thermotoga maritima'' <cite>Comfort2007</cite>.  Correspondingly, GH36 enzymes use a classical [[Koshland double-displacement mechanism]] <cite>Sinnott1990</cite>, like their [[GH27]] relatives in Clan GH-D.  This mechanism involves the formation of a covalent glycosyl-enzyme [[intermediate]] <cite>Vocadlo2001</cite> that partitions predominantly to water in hydrolytic enzymes and to saccharide acceptor substrates in transglycosylating enzymes, such as stachyose and raffinose synthases.
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
Detailed phylogenetic analysis of archaeal GH36 alpha-galactosidases within Clan GH-D originally highlighted likely candidates for the catalytic nucleophile and general acid/base residues in this family, based on protein sequence similarity with those identified in GH27 <cite>3</cite>.  Mutagenesis of the corresponding residues in ''Sulfolobus solfataricus'' alpha-galactosidase GalS dramatically reduced enzyme activity:  the D367G (nucleophile) and D425G (acid/base) mutant had <1 x 10<sup>–3</sup> and 5 x 10<sup>–3</sup> lower activity than the wild type enzyme when assayed against ''p''-nitrophenol-alpha-D-galactopyranoside <cite>3</cite>.  Rescue of the catalytic function of both enzyme mutants was unsuccessful with both azide and formate anions <cite>3</cite>.
+
Detailed phylogenetic analysis of archaeal GH36 &alpha;-galactosidases within [[Sequence-based classification of glycoside hydrolases|Clan]] GH-D originally highlighted likely candidates for the [[catalytic nucleophile]] and [[general acid/base]] residues in this family, based on protein sequence similarity with those identified in [[GH27]] <cite>Brouns2006</cite>.  Mutagenesis of the corresponding residues in ''Sulfolobus solfataricus'' &alpha;-galactosidase GalS dramatically reduced enzyme activity:  the D367G ([[catalytic nucleophile]]) and D425G ([[general acid/base]]) mutant had <1 x 10<sup>–3</sup> and 5 x 10<sup>–3</sup> lower activity than the wild type enzyme when assayed against ''p''-nitrophenyl &alpha;-D-galactopyranoside <cite>Brouns2006</cite>.  Rescue of the catalytic function of both enzyme mutants was unsuccessful with both azide and formate anions <cite>Brouns2006</cite>.
  
The identities for the catalytic residues in GH36 were also confirmed in the ''Thermotoga maritima'' alpha-galactosidase GalA, guided by structural homology with GH27 enzymes <cite>1</cite>.  Site-directed mutation of Asp327 to Gly yielded a variant that had a 200-800-fold lower catalytic rate on aryl galactosides compared with the WT enzyme.  Addition of azide was shown to rescue the ability of the enzyme to hydrolyze ''p''-nitrophenol-alpha-D-galactopyranoside and resulted in formation of  beta-galactopyranosyl azide, confirming Asp327 as the nucleophilic residue.  Mutation of the predicted acid/base residue, Asp387, to Gly reduced activity 1500-fold on ''p''-nitrophenol-alpha-D-galactopyranoside, while addition of azide resulted in formation of alpha-galactopyranosyl azide by nucleophilic attack on the beta-linked glycosyl enzyme.
+
The identities of the catalytic residues in GH36 were also confirmed in the ''Thermotoga maritima'' &alpha;-galactosidase GalA, guided by structural homology with [[GH27]] enzymes <cite>Comfort2007</cite>.  Site-directed mutation of Asp327 to Gly yielded a variant that had a 200-800-fold lower rate on aryl galactosides compared with the WT enzyme.  Addition of azide was shown to rescue the ability of the enzyme to cleave ''p''-nitrophenyl &alpha;-D-galactopyranoside and resulted in formation of  &beta;-galactopyranosyl azide, confirming Asp327 as the [[catalytic nucleophile]].  Mutation of the predicted [[general acid/base]] residue, Asp387, to Gly reduced activity 1500-fold on ''p''-nitrophenyl &alpha;-D-galactopyranoside, while addition of azide resulted in formation of &alpha;-galactopyranosyl azide by nucleophilic attack on the &beta;-linked glycosyl enzyme [[intermediate]].
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
Phylogeny: <cite>3</cite>
+
In June 2005, the first three-dimensional structural coordinates for a member of this family, &alpha;-galactosidase TmGalA from ''Thermotoga maritima'', were deposited by the Joint Center For Structural Genomics (JCSG) (X-ray, 2.34 Å, [{{PDBlink}}1zy9 PDB 1zy9]) <cite>Lesley2002</cite>.  Subsequent analysis of this data in the context of existing structures of [[GH27]] enzymes, revealed homologous active site residues, including two key catalytic Asp residues <cite>Comfort2007 Ernst2006</cite> and a number of conserved substrate-binding residues <cite>Comfort2007</cite>.  The active sites of both [[GH27]] and GH36 enzymes are presented by (&alpha;/&beta;)<sub>8</sub> (TIM) barrel domains.  Both GH36 and [[GH27]] enzymes contain a C-terminal &beta;-sheet domain of unknown function, although this domain is structurally different and more disordered in TmGalA compared with the homologous domain in [[GH27]] (e.g., ''Oryza sativa'' &alpha;-galactosidase, [{{PDBlink}}1uas PDB 1uas]).  Notably, an extra N-terminal, primarily &beta;-sheet domain, which is not found in [[GH27]] enzymes, contributes a key substrate-binding residue (Trp65) to the active site of TmGalA (Trp65, replacing Trp164 in the ''O. sativa'' enzyme). Another notable active site substitution, this time within the TIM barrel itself, is the replacement of the aromatic residues Phe328 and Trp 291 in TmGalA with Ser102 and the Cys101-Cys132 disulfide in the ''O. sativa'' enzyme <cite>Comfort2007</cite>.
Coords: <cite>2</cite>
 
Analysis: <cite>1</cite>
 
  
 +
Detailed phylogenetic analysis of Clan GH-D, originally comprised only of GH36 and [[GH27]], has indicated that archaeal GH36 enzymes are more closely related to plant "alkaline" &alpha;-galactosidases, raffinose synthases, and stachyose synthases than to bacterial and fungal members.  Thermophilic bacterial sequences, such as TmGalA, appear to form a divergent cluster within this latter subgroup <cite>Brouns2006</cite>.  Notably, crystallographic studies on an archeal member of [[GH31]] indicated the structural similarity with both GH36 and [[GH27]], resulting in the unification of these three families into Clan GH-D <cite>Ernst2006</cite>.
  
 
== Family Firsts ==
 
== Family Firsts ==
;First sterochemistry determination: ''Thermotoga maritima'' alpha-galactosidase, by NMR <cite>1</cite>.
+
;First sterochemistry determination: ''Thermotoga maritima'' &alpha;-galactosidase, by NMR <cite>Comfort2007</cite>.
;First catalytic nucleophile identification: ''Sulfolobus solfataricus'' alpha-galactosidase GalS, by sequence homology with GH27 enzymes and mutagenesis <cite>3</cite>.  Subsequently confirmed in ''Thermotoga maritima'' alpha-galactosidase by structural homology, mutagenesis, and azide rescue <cite>1</cite>.
+
;First [[catalytic nucleophile]] identification: ''Sulfolobus solfataricus'' &alpha;-galactosidase GalS, by sequence homology with [[GH27]] enzymes and mutagenesis <cite>Brouns2006</cite>.  Subsequently confirmed in ''Thermotoga maritima'' &alpha;-galactosidase by structural homology, mutagenesis, and azide rescue <cite>Comfort2007</cite>.
;First general acid/base residue identification: ''Sulfolobus solfataricus'' alpha-galactosidase GalS, by sequence homology with GH27 enzymes and mutagenesis <cite>3</cite>.  Subsequently confirmed in ''Thermotoga maritima'' alpha-galactosidase by structural homology, mutagenesis, and azide rescue <cite>1</cite>.
+
;First [[general acid/base]] residue identification: ''Sulfolobus solfataricus'' &alpha;-galactosidase GalS, by sequence homology with [[GH27]] enzymes and mutagenesis <cite>Brouns2006</cite>.  Subsequently confirmed in ''Thermotoga maritima'' &alpha;-galactosidase by structural homology, mutagenesis, and azide rescue <cite>Comfort2007</cite>.
;First 3-D structure: ''Thermotoga maritima'' alpha-galactosidase by X-ray crystallography.  Coordinates ([http://www.rcsb.org/pdb/cgi/explore.cgi?pdbId=1zy9 PDB 1zy9]) deposited in 2005 as part of a high-throughput functional genomics project <cite>2</cite>, first structural analysis reported in 2007 <cite>1</cite>.
+
;First 3-D structure: ''Thermotoga maritima'' &alpha;-galactosidase by X-ray crystallography.  Coordinates ([{{PDBlink}}1zy9 PDB 1zy9]) deposited in 2005 as part of a high-throughput functional genomics project <cite>Lesley2002</cite>, structural analyses published by other groups in 2006 and 2007 <cite>Comfort2007 Ernst2006</cite>.
  
 
== References ==
 
== References ==
 
<biblio>
 
<biblio>
#1 pmid=17323919
+
#Comfort2007 pmid=17323919
#2 pmid=12193646
+
#Lesley2002 pmid=12193646
#3 pmid=16547025
+
#Brouns2006 pmid=16547025
#4 Sinnott, M.L. (1990) Catalytic mechanisms of enzymatic glycosyl transfer. Chem. Rev. 90, 1171-1202. [http://dx.doi.org/10.1021/cr00105a006 DOI: 10.1021/cr00105a006]
+
#Sinnott1990 Sinnott, M.L. (1990) Catalytic mechanisms of enzymic glycosyl transfer. Chem. Rev. 90, 1171-1202. [http://dx.doi.org/10.1021/cr00105a006 DOI: 10.1021/cr00105a006]
#5 pmid=11518970
+
#Vocadlo2001 pmid=11518970
 
+
#Ernst2006 pmid=16580018
 
 
 
 
 
</biblio>
 
</biblio>
  
[[Category:Glycoside Hydrolase Families]]
+
[[Category:Glycoside Hydrolase Families|GH036]]

Latest revision as of 13:20, 18 December 2021

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Glycoside Hydrolase Family GH36
Clan GH-D
Mechanism retaining
Active site residues known
CAZy DB link
https://www.cazy.org/GH36.html

Substrate specificities

Glycoside hydrolases of family 36 exhibit α-galactosidase and α-N-acetylgalactosaminidase activity, which has been demonstrated in archaeal, bacterial, and eukaryotic members of this family. Additionally, certain plant members of this family possess stachyose synthase or raffinose synthase activity.

Kinetics and Mechanism

Family GH36 α-galactosidases are anomeric configuration-retaining enzymes, as first shown by NMR studies on the α-galactosidase GalA from Thermotoga maritima [1]. Correspondingly, GH36 enzymes use a classical Koshland double-displacement mechanism [2], like their GH27 relatives in Clan GH-D. This mechanism involves the formation of a covalent glycosyl-enzyme intermediate [3] that partitions predominantly to water in hydrolytic enzymes and to saccharide acceptor substrates in transglycosylating enzymes, such as stachyose and raffinose synthases.

Catalytic Residues

Detailed phylogenetic analysis of archaeal GH36 α-galactosidases within Clan GH-D originally highlighted likely candidates for the catalytic nucleophile and general acid/base residues in this family, based on protein sequence similarity with those identified in GH27 [4]. Mutagenesis of the corresponding residues in Sulfolobus solfataricus α-galactosidase GalS dramatically reduced enzyme activity: the D367G (catalytic nucleophile) and D425G (general acid/base) mutant had <1 x 10–3 and 5 x 10–3 lower activity than the wild type enzyme when assayed against p-nitrophenyl α-D-galactopyranoside [4]. Rescue of the catalytic function of both enzyme mutants was unsuccessful with both azide and formate anions [4].

The identities of the catalytic residues in GH36 were also confirmed in the Thermotoga maritima α-galactosidase GalA, guided by structural homology with GH27 enzymes [1]. Site-directed mutation of Asp327 to Gly yielded a variant that had a 200-800-fold lower rate on aryl galactosides compared with the WT enzyme. Addition of azide was shown to rescue the ability of the enzyme to cleave p-nitrophenyl α-D-galactopyranoside and resulted in formation of β-galactopyranosyl azide, confirming Asp327 as the catalytic nucleophile. Mutation of the predicted general acid/base residue, Asp387, to Gly reduced activity 1500-fold on p-nitrophenyl α-D-galactopyranoside, while addition of azide resulted in formation of α-galactopyranosyl azide by nucleophilic attack on the β-linked glycosyl enzyme intermediate.

Three-dimensional structures

In June 2005, the first three-dimensional structural coordinates for a member of this family, α-galactosidase TmGalA from Thermotoga maritima, were deposited by the Joint Center For Structural Genomics (JCSG) (X-ray, 2.34 Å, PDB 1zy9) [5]. Subsequent analysis of this data in the context of existing structures of GH27 enzymes, revealed homologous active site residues, including two key catalytic Asp residues [1, 6] and a number of conserved substrate-binding residues [1]. The active sites of both GH27 and GH36 enzymes are presented by (α/β)8 (TIM) barrel domains. Both GH36 and GH27 enzymes contain a C-terminal β-sheet domain of unknown function, although this domain is structurally different and more disordered in TmGalA compared with the homologous domain in GH27 (e.g., Oryza sativa α-galactosidase, PDB 1uas). Notably, an extra N-terminal, primarily β-sheet domain, which is not found in GH27 enzymes, contributes a key substrate-binding residue (Trp65) to the active site of TmGalA (Trp65, replacing Trp164 in the O. sativa enzyme). Another notable active site substitution, this time within the TIM barrel itself, is the replacement of the aromatic residues Phe328 and Trp 291 in TmGalA with Ser102 and the Cys101-Cys132 disulfide in the O. sativa enzyme [1].

Detailed phylogenetic analysis of Clan GH-D, originally comprised only of GH36 and GH27, has indicated that archaeal GH36 enzymes are more closely related to plant "alkaline" α-galactosidases, raffinose synthases, and stachyose synthases than to bacterial and fungal members. Thermophilic bacterial sequences, such as TmGalA, appear to form a divergent cluster within this latter subgroup [4]. Notably, crystallographic studies on an archeal member of GH31 indicated the structural similarity with both GH36 and GH27, resulting in the unification of these three families into Clan GH-D [6].

Family Firsts

First sterochemistry determination
Thermotoga maritima α-galactosidase, by NMR [1].
First catalytic nucleophile identification
Sulfolobus solfataricus α-galactosidase GalS, by sequence homology with GH27 enzymes and mutagenesis [4]. Subsequently confirmed in Thermotoga maritima α-galactosidase by structural homology, mutagenesis, and azide rescue [1].
First general acid/base residue identification
Sulfolobus solfataricus α-galactosidase GalS, by sequence homology with GH27 enzymes and mutagenesis [4]. Subsequently confirmed in Thermotoga maritima α-galactosidase by structural homology, mutagenesis, and azide rescue [1].
First 3-D structure
Thermotoga maritima α-galactosidase by X-ray crystallography. Coordinates (PDB 1zy9) deposited in 2005 as part of a high-throughput functional genomics project [5], structural analyses published by other groups in 2006 and 2007 [1, 6].

References

  1. Comfort DA, Bobrov KS, Ivanen DR, Shabalin KA, Harris JM, Kulminskaya AA, Brumer H, and Kelly RM. (2007). Biochemical analysis of Thermotoga maritima GH36 alpha-galactosidase (TmGalA) confirms the mechanistic commonality of clan GH-D glycoside hydrolases. Biochemistry. 2007;46(11):3319-30. DOI:10.1021/bi061521n | PubMed ID:17323919 [Comfort2007]
  2. Sinnott, M.L. (1990) Catalytic mechanisms of enzymic glycosyl transfer. Chem. Rev. 90, 1171-1202. DOI: 10.1021/cr00105a006

    [Sinnott1990]
  3. Vocadlo DJ, Davies GJ, Laine R, and Withers SG. (2001). Catalysis by hen egg-white lysozyme proceeds via a covalent intermediate. Nature. 2001;412(6849):835-8. DOI:10.1038/35090602 | PubMed ID:11518970 [Vocadlo2001]
  4. Brouns SJ, Smits N, Wu H, Snijders AP, Wright PC, de Vos WM, and van der Oost J. (2006). Identification of a novel alpha-galactosidase from the hyperthermophilic archaeon Sulfolobus solfataricus. J Bacteriol. 2006;188(7):2392-9. DOI:10.1128/JB.188.7.2392-2399.2006 | PubMed ID:16547025 [Brouns2006]
  5. Lesley SA, Kuhn P, Godzik A, Deacon AM, Mathews I, Kreusch A, Spraggon G, Klock HE, McMullan D, Shin T, Vincent J, Robb A, Brinen LS, Miller MD, McPhillips TM, Miller MA, Scheibe D, Canaves JM, Guda C, Jaroszewski L, Selby TL, Elsliger MA, Wooley J, Taylor SS, Hodgson KO, Wilson IA, Schultz PG, and Stevens RC. (2002). Structural genomics of the Thermotoga maritima proteome implemented in a high-throughput structure determination pipeline. Proc Natl Acad Sci U S A. 2002;99(18):11664-9. DOI:10.1073/pnas.142413399 | PubMed ID:12193646 [Lesley2002]
  6. Ernst HA, Lo Leggio L, Willemoës M, Leonard G, Blum P, and Larsen S. (2006). Structure of the Sulfolobus solfataricus alpha-glucosidase: implications for domain conservation and substrate recognition in GH31. J Mol Biol. 2006;358(4):1106-24. DOI:10.1016/j.jmb.2006.02.056 | PubMed ID:16580018 [Ernst2006]

All Medline abstracts: PubMed