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Glycoside Hydrolase Family 33
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- Author: ^^^Tom Wennekes^^^
- Responsible Curator: ^^^Steve Withers^^^
Glycoside Hydrolase Family GH33 | |
Clan | GH-x |
Mechanism | retaining/inverting |
Active site residues | known/not known |
CAZy DB link | |
https://www.cazy.org/GH33.html |
Substrate specificities
Sialic acids, often known as N-acetylneuraminic acid (Neu5Ac, NANA, NeuNAc, NeuNA), are a family of nine carbon monosaccharides with a carboxylate group in the carbon 1 position that occupy the terminal position of the glycans, glycoproteins, glycolipids, and polysaccharides in cells and play important roles in interactions of the cell with its environment [1]. More than 50 sialic acid derivatives have been detected in eukaryotic and prokaryotic species; the most frequently detected sialic acids have an α(2,3) or α(2,6) linkage to galactose, N-acetylgalactosamine, and N-acetylglucosamine or an α(2,8) linkage to another sialic acids [2, 3, 4]. Sialic acids are hydrolyzed by sialidases (E.C. 3.2.1.18), and these enzymes are categorized into four different glycoside hydrolase(GH) families: GH33, GH34, and GH83 families are exosialidases while GH53 is an endosialidase [5].
GH33 includes most bacterial and simple eukaryotic sialidases and trans-sialidases [6]. Members of GH33 exhibit different preferences for the three most common sialic acid linkage types listed above, despite similar protein structure. For example, sialidases from Salmonella typhimurium LT2, Vibrio Cholerae, and Clostridium septicum, Clostridium sordellii, Clostridium chauvoei, Clostridium tertium demonstrate a higher hydrolysis activity towards α(2,3) linked substrates than α(2,6) linked substrates, while sialidases from Corynebacteriumm diphtheria and Micromonospora viridifaciens prefer to hydrolyze substrates with α(2,6) linkages [2]. One organism may produce sialidase isoenzymes with different substrate preferences. Pasteurella multocida produces two sialidases with different substrate preferences: NanH, an extracellular enzyme favouring α(2,3)-linked sialyllactose over α(2,6)-linked sialyllactose and NanB, a membrane bound enzyme that prefers α(2,6)-linked substrates over α(2,3)-linked substrates [7]. Similarly, membrane-bound NanA of Salmonella pneumoniae displays similar hydrolysis rates for sialyllactoses with α(2,3)-, α(2,6)- and α(2,8)-linkages whereas extracellular NanB from the same organism prefers α(2,3) linkage over substrates with the other two linkage types [2].
Kinetics and Mechanism
Sialidases and trans-sialidases hydrolyse or transfer sialic acids with retention of the anomeric configuration. Considerable debate had occurred over whether an ionic or covalent intermediate was formed. However, a glycosyl-enzyme intermediate was observed on T. cruzi trans-sialidase(TcTS) by mass spectrometry using a fluorinated sialic acid analogue, and the subsequent crystal structures helped to determine the mechanism of the bacterial sialidases [6, 8]. Kinetic analysis of TcTS revealed a ping-pong double-displacement mechanism, and a covalent intermediate was demonstrated, without use of a fluorinated derivative, by use of mass spectrometry [9]. Subsequent structural studies of two strictly hydrolytic sialidases from T. rangelli [10] and C. perfringens [11] also characterised their covalent intermediates.
Catalytic Residues
The strictly conserved tyrosine in the active site acts as the nucleophile attacking the anomeric centre of the sialic acid [6]. Peptide mapping of T. cruzi with the fluorinated sialic acid identified the catalytic nucleophile as Tyr342 [8]. The nucleophilic character of Tyr342 is enhanced by interaction with a nearby invariant glutamate, which acts as a base catalyst. Tyrosine has likely evolved as the catalytic nucleophile rather than the carboxylate group normally found in glycosidases in order to minimize charge repulsion with the carboxylate at C1 of the sialic acid [6, 11]. The 20 fold increase of Km when the Tyr is mutated to Asp also supports the need to minimize the Coulombic repulsion between the enzyme and the substrate [12].
An Asp in the active site within hydrogen bonding distance of the glycosidic oxygen acts as the acid catalyst for the initial glycosyl-enzyme formation. After glycosyl-enzyme formation, the same Asp acts as the general base catalyst for nucleophilic attack by the 3-OH of lactose. The role of Asp as the acid catalyst has been contested in the early 90s due to the low pKa values arising from the exposure to the solvent [6, 13, 14]. However, Michaelis complex of T. cruzi demonstrated that the pKa value of Asp can be raised significantly to perform the role as an acid catalyst because of the position of the Tyr119 aromatic ring and the binding of the aglycone of the substrate that decrease the solvent exposure of said Asp residue [6].
Three-dimensional structures
All members of the sialidase superfamily, including the members of GH34 and GH83, display a 6 bladed beta-propeller sheet catalytic domain [6], which is accepted as the canonical neuraminidase fold. All bacterial sialidases generally have four to five aspartate boxes (Asp-box, Ser/Thr-x-Asp-x-Gly-x-Thr-Trp/Phe; where x represents any amino acid) within the catalytic domain, and these repeated sequences are found in identical positions in the beta sheet fold, far from the active site.
The catalytic site structure is strictly conserved in all three families and contains an arginine triad which binds to the carboxylate in the C1 position of the sialic acid, a Tyr/Glu nucleophilic pair, and an aspartic acid that acts as the acid/base catalyst [5].
Bacterial sialidases may also contain a membrane binding domain, signal domain and a lectin-like domain. Although not all bacterial sialidases have a lectin domain, the lectin domain can be used to recognize the sialic acid in certain species, such as V. cholerae [15]. Also it is not uncommon for a bacterial sialidase to have a carbohydrate binding module (CBM) as one of its domains, such as in M. viridifaciens sialidase [16, 17].
Family Firsts
- First stereochemistry determination
- Cite some reference here, with a short (1-2 sentence) explanation [18].
- First catalytic nucleophile identification
- Cite some reference here, with a short (1-2 sentence) explanation [19].
- First general acid/base residue identification
- Cite some reference here, with a short (1-2 sentence) explanation [20].
- First 3-D structure
- Cite some reference here, with a short (1-2 sentence) explanation [21].
References
- Varki A (1997). Sialic acids as ligands in recognition phenomena. FASEB J. 1997;11(4):248-55. DOI:10.1096/fasebj.11.4.9068613 |
- Kim S, Oh DB, Kang HA, and Kwon O. (2011). Features and applications of bacterial sialidases. Appl Microbiol Biotechnol. 2011;91(1):1-15. DOI:10.1007/s00253-011-3307-2 |
- Varki A (2007). Glycan-based interactions involving vertebrate sialic-acid-recognizing proteins. Nature. 2007;446(7139):1023-9. DOI:10.1038/nature05816 |
- Vimr ER, Kalivoda KA, Deszo EL, and Steenbergen SM. (2004). Diversity of microbial sialic acid metabolism. Microbiol Mol Biol Rev. 2004;68(1):132-53. DOI:10.1128/MMBR.68.1.132-153.2004 |
- Buschiazzo A and Alzari PM. (2008). Structural insights into sialic acid enzymology. Curr Opin Chem Biol. 2008;12(5):565-72. DOI:10.1016/j.cbpa.2008.06.017 |
- Amaya MF, Watts AG, Damager I, Wehenkel A, Nguyen T, Buschiazzo A, Paris G, Frasch AC, Withers SG, and Alzari PM. (2004). Structural insights into the catalytic mechanism of Trypanosoma cruzi trans-sialidase. Structure. 2004;12(5):775-84. DOI:10.1016/j.str.2004.02.036 |
- Mizan S, Henk A, Stallings A, Maier M, and Lee MD. (2000). Cloning and characterization of sialidases with 2-6' and 2-3' sialyl lactose specificity from Pasteurella multocida. J Bacteriol. 2000;182(24):6874-83. DOI:10.1128/JB.182.24.6874-6883.2000 |
- Watts AG, Damager I, Amaya ML, Buschiazzo A, Alzari P, Frasch AC, and Withers SG. (2003). Trypanosoma cruzi trans-sialidase operates through a covalent sialyl-enzyme intermediate: tyrosine is the catalytic nucleophile. J Am Chem Soc. 2003;125(25):7532-3. DOI:10.1021/ja0344967 |
- Damager I, Buchini S, Amaya MF, Buschiazzo A, Alzari P, Frasch AC, Watts A, and Withers SG. (2008). Kinetic and mechanistic analysis of Trypanosoma cruzi trans-sialidase reveals a classical ping-pong mechanism with acid/base catalysis. Biochemistry. 2008;47(11):3507-12. DOI:10.1021/bi7024832 |
- Newstead SL, Potter JA, Wilson JC, Xu G, Chien CH, Watts AG, Withers SG, and Taylor GL. (2008). The structure of Clostridium perfringens NanI sialidase and its catalytic intermediates. J Biol Chem. 2008;283(14):9080-8. DOI:10.1074/jbc.M710247200 |
- Chong AK, Pegg MS, Taylor NR, and von Itzstein M. (1992). Evidence for a sialosyl cation transition-state complex in the reaction of sialidase from influenza virus. Eur J Biochem. 1992;207(1):335-43. DOI:10.1111/j.1432-1033.1992.tb17055.x |
- Burmeister WP, Henrissat B, Bosso C, Cusack S, and Ruigrok RW. (1993). Influenza B virus neuraminidase can synthesize its own inhibitor. Structure. 1993;1(1):19-26. DOI:10.1016/0969-2126(93)90005-2 |
- Gaskell A, Crennell S, and Taylor G. (1995). The three domains of a bacterial sialidase: a beta-propeller, an immunoglobulin module and a galactose-binding jelly-roll. Structure. 1995;3(11):1197-205. DOI:10.1016/s0969-2126(01)00255-6 |
- Watson JN, Newstead S, Narine AA, Taylor G, and Bennet AJ. (2005). Two nucleophilic mutants of the Micromonospora viridifaciens sialidase operate with retention of configuration by two different mechanisms. Chembiochem. 2005;6(11):1999-2004. DOI:10.1002/cbic.200500114 |
- Watts AG, Oppezzo P, Withers SG, Alzari PM, and Buschiazzo A. (2006). Structural and kinetic analysis of two covalent sialosyl-enzyme intermediates on Trypanosoma rangeli sialidase. J Biol Chem. 2006;281(7):4149-55. DOI:10.1074/jbc.M510677200 |
- Moustafa I, Connaris H, Taylor M, Zaitsev V, Wilson JC, Kiefel MJ, von Itzstein M, and Taylor G. (2004). Sialic acid recognition by Vibrio cholerae neuraminidase. J Biol Chem. 2004;279(39):40819-26. DOI:10.1074/jbc.M404965200 |