Mutagenesis of the Conserved Active-Site Tyrosine Changes a Retaining Sialidase into an Inverting Sialidase

Watson, Jacqueline N.; Dookhun, Veedeeta; Borgford, Thor J.; Bennet, Andrew J.

doi:10.1021/bi035396g

Cited by 74 publications

(143 citation statements)

References 35 publications

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“…However, as the authors stress (31), the high residual activities for the nucleophile mutants might be a trait of this particular bacterial sialidase, because equivalent mutations in other sialidases result in complete inactivation. Furthermore, the catalytic rates of the mutants are critically dependent on the aglyconeleaving group ability in contrast to the behavior of the wild-type enzyme, which shows higher k cat values (Ͼ10 4 ) when working with natural substrates, such as ␣-2,6-and ␣-2,3-sialyl-lactose (29,31). In the absence of the naturally selected nucleophilic tyrosine, which is strictly conserved in all known exosialidases, compensation by alternative chemical groups appears to take place on the M. viridifaciens mutants, with reaction occurring via several different mechanisms (29,31).…”

Section: Discussionmentioning

confidence: 99%

Structural and Kinetic Analysis of Two Covalent Sialosyl-Enzyme Intermediates on Trypanosoma rangeli Sialidase

Watts

Oppezzo

Withers

et al. 2006

Journal of Biological Chemistry

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Trypanosoma rangeli sialidase is a glycoside hydrolase (family GH33) that catalyzes the cleavage of ␣-233-linked sialic acid residues from sialoglycoconjugates with overall retention of anomeric configuration. Retaining glycosidases usually operate through a ping-pong mechanism, wherein a covalent intermediate is formed between the carbohydrate and an active site carboxylic acid of the enzyme. Sialidases, instead, appear to use a tyrosine as the catalytic nucleophile, leaving the possibility of an essentially different catalytic mechanism. Indeed, a direct nucleophilic role for a tyrosine was shown for the homologous trans-sialidase from Trypanosoma cruzi, although itself not a typical sialidase. Here we present the three-dimensional structures of the covalent glycosyl-enzyme complexes formed by the T. rangeli sialidase with two different mechanism-based inactivators at 1.9 and 1.7 Å resolution. To our knowledge, these are the first reported structures of enzymatically competent covalent intermediates for a strictly hydrolytic sialidase. Kinetic analyses have been carried out on the formation and turnover of both intermediates, showing that structural modifications to these inactivators can be used to modify the lifetimes of covalent intermediates. These results provide further evidence that all sialidases likely operate through a similar mechanism involving the transient formation of a covalently sialylated enzyme. Furthermore, we believe that the ability to "tune" the inactivation and reactivation rates of mechanism-based inactivators toward specific enzymes represents an important step toward developing this class of inactivators into therapeutically useful compounds.Sialidases are enzymes that catalyze the hydrolysis or trans-glycosylation (trans-sialidases) of sialic acid residues from various glycoconjugates. Exosialidases (E.C. 3.2.1.18) remove terminal sialyl residues with overall retention of the stereoisomeric configuration of the anomeric carbon. Endosialidases (E.C. 3.2.1.129) on the other hand, break the internal glycosidic bonds present in 2,8-linked sialic acid oligomers or polymers (colominic acid). Although these two enzyme classes share important structural features, including the catalytic ␤-propeller domain and several residues that interact directly with the sialyl moiety (1, 2), sequence similarity is very low, and they use different mechanisms to catalyze the hydrolysis of the glycosidic linkage (2, 3). The great majority of exosialidases have been classified into three different sequence-based families, GH33, -34, and -83 (4). Naturally sialylated glycoconjugates include a variety of glycoproteins, glycopeptides, glycolipids, and cell-surface oligosaccharides (5). These glycoconjugates mediate a wide range of crucial biological processes, such as cell-cell communication and signal transduction events (6, 7), as well as being involved in a variety of host-pathogen interactions (8). As such, sialidases represent attractive targets for chemical intervention in the treatment of various diseas...

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Section: Discussionmentioning

confidence: 99%

Structural and Kinetic Analysis of Two Covalent Sialosyl-Enzyme Intermediates on Trypanosoma rangeli Sialidase

Watts

Oppezzo

Withers

et al. 2006

Journal of Biological Chemistry

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“…Retaining NA mechanisms, on the other hand, appear to be quite distinct. Biochemical analysis of NA from various microorganisms has revealed that a conserved active-site tyrosine can function as a nucleophile and may be the most important catalytic residue [17][18][19] .…”

mentioning

confidence: 99%

Influenza neuraminidase operates via a nucleophilic mechanism and can be targeted by covalent inhibitors

et al. 2013

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“…A tyrosine residue is a neutral nucleophile, but requires a general base to enhance its nucleophilicity. This mechanism was implied from X-ray structures, and was supported by experiments involving trapping of the intermediate with fluoro sugars followed by peptide mapping and then crystallography [6,7], and also through mechanism studies on mutants [8] (Figure 7). …”

Section: Alternative Nucleophilesmentioning

confidence: 74%

“…As members of Clan GH-A they have a classical (α/β) 8 TIM barrel fold with the two key active site glutamic acids being approximately 200 residues apart in sequence and located at the C-terminal ends of β-strands 4 (acid/base) and 7 (nucleophile) [15,16].…”

Section: Three-dimensional Structures Of Gh1mentioning

confidence: 99%

Extremophilic Carbohydrate Active Enzymes (CAZymes)

Lee¹,

Park²,

Park³

2017

JNHFE

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Carbohydrate active enzymes (CAZymes) are a large class of enzymes, which build and breakdown the complex carbohydrates of the cell. On the basis of their amino acid sequences they are classified in families that show conserved catalytic mechanism, structure, and active site residues, but may conflict each other in substrate specificity. The CAZymes provides a continuously updated list of the glycoside hydrolase families, GHs. This group of enzymes is classified based on functional similarity, but today they are classified into 108 GHs on the basis of amino acid sequence similarity. Despite their similarities to enzymes with known functions, their primary functions are still unclear. Based on these criteria, β-galactosidase activities are now divided into four different families: GH1, GH2, GH35 and GH42, among which the better studied GH2 includes β-galactosidase from Escherichia coli, Aspergillus, Bacillus megatherium, and Sulfolobus solfataricus, while those from thermophilic, psychrophilic and halophilic organisms belong to GH42. Lactase is often confused as an alternate name for β-galactosidase, but it is actually simply a subclass (small subunit) of β-galactosidase.(β-D-galactoside galactohydrolase, EC 3.2.1.23) that catalyses hydrolysis of the galactosyl moiety from non-reducing termini of oligosaccharides or from glycosides. Most genes encoding GH42 enzymes are from prokaryotes that are unable to grow on lactose as a sole carbon source and at least two GH42 β-galactosidase do not cleave lactose in vitro. The determination of growth on lactose can be complicated by the multiple β-galactosidases because not all of the β-galactosidase is acting as lactases in vitro. Β-Galactosidase hydrolyses the β-1, 4-D-galactosidic linkage of lactose, as well as those of related chromogens, o-nitrophenyl-β-dgalactopyranoside (ONPG), p-nitrophenyl-β-d-galactopyranoside (PNPG) and 6-bromo-2-naphthyl-galactopyranoside (BNG). This enzyme has been purified and characterized from various sources, including plants, animals, and many microorganisms. In humans, lactase is present predominantly along the brush border membrane of the differentiated enterocytes lining the villi of the small intestine. Lactase is essential for digestive hydrolysis of lactose in milk. Deficiency of the enzyme causes lactose intolerance. Several 3D structures are available for the GH1 and GH2 β-galactosidase for which the catalytic residues have experimentally been determined, while three 3D structures of β-galactosidase from E. coli, Penicillium sp and Thermus thermophilus A4 are available for both the GH35 and GH42 families. Glycoside hydrolasesGlycoside hydrolases are enzymes that catalyze the hydrolysis of the glycosidic linkage of glycosides, leading to the formation of a sugar hemiacetal or hemiketal and the corresponding free aglycon. Glycoside hydrolases are also referred to as glycosidases, and sometimes also as glycosyl hydrolases. Glycoside hydrolases can catalyze the hydrolysis of O-, N-and S-linked glycosides ( Figure 1). Endo/Exo:Exo / ...

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Mutagenesis of the Conserved Active-Site Tyrosine Changes a Retaining Sialidase into an Inverting Sialidase

Cited by 74 publications

References 35 publications

Structural and Kinetic Analysis of Two Covalent Sialosyl-Enzyme Intermediates on Trypanosoma rangeli Sialidase

Structural and Kinetic Analysis of Two Covalent Sialosyl-Enzyme Intermediates on Trypanosoma rangeli Sialidase

Influenza neuraminidase operates via a nucleophilic mechanism and can be targeted by covalent inhibitors

Extremophilic Carbohydrate Active Enzymes (CAZymes)

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