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Difference between revisions of "Glycoside Hydrolase Family 145"
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== Substrate specificities == | == Substrate specificities == | ||
| − | Two members of this family have been shown to be α-L-rhamnosidases, targeting rhamnose linked α-1,4 to glucuronic acid in the complex arabinogalactan protein gum arabic. | + | Two members of this family have been shown to be an exo-α-L-rhamnosidases, targeting rhamnose linked α-1,4 to glucuronic acid in the complex arabinogalactan protein gum arabic <cite>Munoz-Munoz2017 Cartmell2019</cite>. |
== Kinetics and Mechanism == | == Kinetics and Mechanism == | ||
| − | NMR, using the arabinogalactan protein (AGP) gum arabic as the substrate, revealed the family operates via a retaining mechanism. Rather than using a standard double displacement mechanism the enzyme is speculatively predicted to perform catalysis via an epoxide intermediate, similar to GH99 enzymes. GH145, however, is proposed to perform catalysis via a substrate assisted mechanism, requiring the carboxyl group of the glucuronic acid and a single catalytic histidine; both acting as an acid/base. This histidine is predicted to deprotonate the O2 of rhamnose, allowing O2 to attack C1 and form an epoxide. Simultaneously the carboxyl group of the glucuronic acid may deprotonate a water molecule generating a hydroxyl group to attach the C1 of rhamnose and allowing protonation of its own O4 thus, leading to glycosidic bond cleavage. Further work is needed to confirm the mechanism by which GH145 operates. | + | NMR, using the arabinogalactan protein (AGP) gum arabic as the substrate, revealed the family operates via a retaining mechanism <cite>Munoz-Munoz2017</cite>. Rather than using a standard double displacement mechanism the enzyme is speculatively predicted to perform catalysis via an epoxide intermediate, similar to GH99 enzymes <cite>Thompson2012 Fernandes2018</cite>. GH145, however, is proposed to perform catalysis via a substrate assisted mechanism, requiring the carboxyl group of the glucuronic acid and a single catalytic histidine; both acting as an acid/base. This histidine is predicted to deprotonate the O2 of rhamnose, allowing O2 to attack C1 and form an epoxide. Simultaneously the carboxyl group of the glucuronic acid may deprotonate a water molecule generating a hydroxyl group to attach the C1 of rhamnose and allowing protonation of its own O4 thus, leading to glycosidic bond cleavage <cite>Munoz-Munoz2017</cite>. Further work is needed to confirm the mechanism by which GH145 operates. |
| − | |||
== Catalytic Residues == | == Catalytic Residues == | ||
| − | A single catalytic histidine has been shown to be critical for activity. The introduction of the catalytic histidine into related enzymes, which lack the histidine and rhamnosidase activity, is sufficient to introduce rhamnosidase activity into these enzymes. | + | A single catalytic histidine has been shown to be critical for activity. The introduction of the catalytic histidine into related enzymes, which lack the histidine and rhamnosidase activity, is sufficient to introduce rhamnosidase activity into these enzymes <cite>Munoz-Munoz2017</cite>. |
== Three-dimensional structures == | == Three-dimensional structures == | ||
| − | GH145 comprise a single domain which is a seven bladed β-propeller fold. Each blade is composed of four anti parallel β-strands that extend out radially from the central core. The final blade is formed by strands from both the N- and C-terminus of the protein which is termed as 'molecular velcro' and is believed to add considerable stability to the fold. The active site of these α-L-rhamnosidases is located on the opposite side, termed the posterior surface, of CAZymes with similar β-propeller folds. The "normal" side, termed the anterior surface, of the β-propeller bears the highest residue conservation and may well have another function. GH145 is distantly related to PL25 which utilise the anterior surface suggesting that the this surface in GH145 may have another activity. | + | GH145 comprise a single domain which is a seven bladed β-propeller fold. Each blade is composed of four anti parallel β-strands that extend out radially from the central core. The final blade is formed by strands from both the N- and C-terminus of the protein which is termed as 'molecular velcro' and is believed to add considerable stability to the fold. The active site of these α-L-rhamnosidases is located on the opposite side, termed the posterior surface, of CAZymes with similar β-propeller folds. The "normal" side, termed the anterior surface, of the β-propeller bears the highest residue conservation and may well have another function. GH145 is distantly related to [[PL25]] which utilise the anterior surface suggesting that the this surface in GH145 may have another activity <cite>Munoz-Munoz2017 Ulaganathan2017</cite>. |
== Family Firsts == | == Family Firsts == | ||
| − | ;First stereochemistry determination: Determined for the bacteroides thetaiotaomicron enzyme BT3686 | + | ;First stereochemistry determination: Determined for the bacteroides thetaiotaomicron enzyme BT3686 <cite>Munoz-Munoz2017</cite>. |
| − | ;First catalytic acid/base residue identification: Predicted to be a histidine | + | ;First catalytic acid/base residue identification: Predicted to be a histidine <cite>Munoz-Munoz2017</cite>. |
| − | ;Second general acid/base residue identification: Predicted to be provided by the substrate. | + | ;Second general acid/base residue identification: Predicted to be provided by the substrate <cite>Munoz-Munoz2017</cite>. |
| − | ;First 3-D structure: BT3686, BACINT_00347 and BACCELL_00856 were the first enzymes to have their structures solved. | + | ;First 3-D structure: BT3686, BACINT_00347 and BACCELL_00856 were the first enzymes to have their structures solved <cite>Munoz-Munoz2017</cite>. |
| − | |||
| − | |||
== References == | == References == | ||
<biblio> | <biblio> | ||
| + | #Munoz-Munoz2017 pmid=28396425 | ||
| + | #Cartmell2019 pmid=31541200 | ||
| + | #Thompson2012 pmid=22219371 | ||
| + | #Fernandes2018 pmid=29508463 | ||
| + | #Ulaganathan2017 pmid=28290654 | ||
#Cantarel2009 pmid=18838391 | #Cantarel2009 pmid=18838391 | ||
#DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [http://www.biochemist.org/bio/03004/0026/030040026.pdf Download PDF version]. | #DaviesSinnott2008 Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. ''The Biochemist'', vol. 30, no. 4., pp. 26-32. [http://www.biochemist.org/bio/03004/0026/030040026.pdf Download PDF version]. | ||
</biblio> | </biblio> | ||
| − | + | ||
[[Category:Glycoside Hydrolase Families|GH145]] | [[Category:Glycoside Hydrolase Families|GH145]] | ||
Revision as of 12:23, 27 January 2020
This page is currently under construction. This means that the Responsible Curator has deemed that the page's content is not quite up to CAZypedia's standards for full public consumption. All information should be considered to be under revision and may be subject to major changes.
- Author: ^^^Alan Cartmell^^^
- Responsible Curator: ^^^Harry Gilbert^^^
| Glycoside Hydrolase Family GH145 | |
| Clan | GH-x |
| Mechanism | retaining |
| Active site residues | known |
| CAZy DB link | |
| http://www.cazy.org/GH145.html | |
Substrate specificities
Two members of this family have been shown to be an exo-α-L-rhamnosidases, targeting rhamnose linked α-1,4 to glucuronic acid in the complex arabinogalactan protein gum arabic [1, 2].
Kinetics and Mechanism
NMR, using the arabinogalactan protein (AGP) gum arabic as the substrate, revealed the family operates via a retaining mechanism [1]. Rather than using a standard double displacement mechanism the enzyme is speculatively predicted to perform catalysis via an epoxide intermediate, similar to GH99 enzymes [3, 4]. GH145, however, is proposed to perform catalysis via a substrate assisted mechanism, requiring the carboxyl group of the glucuronic acid and a single catalytic histidine; both acting as an acid/base. This histidine is predicted to deprotonate the O2 of rhamnose, allowing O2 to attack C1 and form an epoxide. Simultaneously the carboxyl group of the glucuronic acid may deprotonate a water molecule generating a hydroxyl group to attach the C1 of rhamnose and allowing protonation of its own O4 thus, leading to glycosidic bond cleavage [1]. Further work is needed to confirm the mechanism by which GH145 operates.
Catalytic Residues
A single catalytic histidine has been shown to be critical for activity. The introduction of the catalytic histidine into related enzymes, which lack the histidine and rhamnosidase activity, is sufficient to introduce rhamnosidase activity into these enzymes [1].
Three-dimensional structures
GH145 comprise a single domain which is a seven bladed β-propeller fold. Each blade is composed of four anti parallel β-strands that extend out radially from the central core. The final blade is formed by strands from both the N- and C-terminus of the protein which is termed as 'molecular velcro' and is believed to add considerable stability to the fold. The active site of these α-L-rhamnosidases is located on the opposite side, termed the posterior surface, of CAZymes with similar β-propeller folds. The "normal" side, termed the anterior surface, of the β-propeller bears the highest residue conservation and may well have another function. GH145 is distantly related to PL25 which utilise the anterior surface suggesting that the this surface in GH145 may have another activity [1, 5].
Family Firsts
- First stereochemistry determination
- Determined for the bacteroides thetaiotaomicron enzyme BT3686 [1].
- First catalytic acid/base residue identification
- Predicted to be a histidine [1].
- Second general acid/base residue identification
- Predicted to be provided by the substrate [1].
- First 3-D structure
- BT3686, BACINT_00347 and BACCELL_00856 were the first enzymes to have their structures solved [1].
References
- Munoz-Munoz J, Cartmell A, Terrapon N, Henrissat B, and Gilbert HJ. (2017). Unusual active site location and catalytic apparatus in a glycoside hydrolase family. Proc Natl Acad Sci U S A. 2017;114(19):4936-4941. DOI:10.1073/pnas.1701130114 |
- Cartmell A, Muñoz-Muñoz J, Briggs JA, Ndeh DA, Lowe EC, Baslé A, Terrapon N, Stott K, Heunis T, Gray J, Yu L, Dupree P, Fernandes PZ, Shah S, Williams SJ, Labourel A, Trost M, Henrissat B, and Gilbert HJ. (2019). Author Correction: A surface endogalactanase in Bacteroides thetaiotaomicron confers keystone status for arabinogalactan degradation. Nat Microbiol. 2019;4(11):2021-2023. DOI:10.1038/s41564-019-0584-5 |
- Thompson AJ, Williams RJ, Hakki Z, Alonzi DS, Wennekes T, Gloster TM, Songsrirote K, Thomas-Oates JE, Wrodnigg TM, Spreitz J, Stütz AE, Butters TD, Williams SJ, and Davies GJ. (2012). Structural and mechanistic insight into N-glycan processing by endo-α-mannosidase. Proc Natl Acad Sci U S A. 2012;109(3):781-6. DOI:10.1073/pnas.1111482109 |
- Fernandes PZ, Petricevic M, Sobala L, Davies GJ, and Williams SJ. (2018). Exploration of Strategies for Mechanism-Based Inhibitor Design for Family GH99 endo-α-1,2-Mannanases. Chemistry. 2018;24(29):7464-7473. DOI:10.1002/chem.201800435 |
- Ulaganathan T, Boniecki MT, Foran E, Buravenkov V, Mizrachi N, Banin E, Helbert W, and Cygler M. (2017). New Ulvan-Degrading Polysaccharide Lyase Family: Structure and Catalytic Mechanism Suggests Convergent Evolution of Active Site Architecture. ACS Chem Biol. 2017;12(5):1269-1280. DOI:10.1021/acschembio.7b00126 |
- Cantarel BL, Coutinho PM, Rancurel C, Bernard T, Lombard V, and Henrissat B. (2009). The Carbohydrate-Active EnZymes database (CAZy): an expert resource for Glycogenomics. Nucleic Acids Res. 2009;37(Database issue):D233-8. DOI:10.1093/nar/gkn663 |
-
Davies, G.J. and Sinnott, M.L. (2008) Sorting the diverse: the sequence-based classifications of carbohydrate-active enzymes. The Biochemist, vol. 30, no. 4., pp. 26-32. Download PDF version.