Jacqueline N. Watson

Galactose recognition by the carbohydrate-binding module of a bacterial sialidase

Glycoside hydrolases often possess carbohydrate-binding modules (CBMs) in addition to their catalytic domains, which help target the enzymes to appropriate substrates and thereby increase their catalytic efficiency. Sialidases hydrolyse the release of sialic acid from a variety of glycoconjugates and play significant roles in the pathogenesis of a number of important diseases. The sialidase from Micromonospora viridifaciens has a CBM which recognizes galactose. The CBM is linked to the catalytic domain by an immunoglobulin-like domain, resulting in the galactose binding site sitting above the catalytic site, suggesting an interplay between the two sites. By studying nine crystallographically independent structures of the M. viridifaciens sialidase, the relative flexibility of the three domains was analysed. A detailed study is also presented of the recognition of galactose and lactose by the M. viridifaciens CBM. The striking structure of this sialidase suggests a role for the CBM in binding to galactose residues unmasked by the adjacent catalytic site.

Contribution of the Active Site Aspartic Acid to Catalysis in the Bacterial Neuraminidase from Micromonospora Viridifaciens

A recombinant D92G mutant sialidase from Micromonospora viridifaciens has been cloned, expressed and purified. Kinetic studies reveal that the replacement of the conserved aspartic acid with glycine results in a catalytically competent retaining sialidase that possesses significant activity against activated substrates. The contribution of this aspartate residue to the free energy of hydrolysis for natural substrates is greater than 19 kJ/mol. The three dimensional structure of the D92G mutant shows that the removal of aspartic acid 92 causes no significant re‐arrangement of the active site, and that an ordered water molecule substitutes for the carboxylate group of D92.

Two nucleophilic mutants of the Micromonospora viridifaciens sialidase operate with retention of configuration by two different mechanisms.

Mutants of the Micromonospora viridifaciens sialidase, Y370E and Y370F, are catalytically active retaining enzymes that operate by different mechanisms. Previous substitutions with smaller amino acids, including Y370D, yielded inverting sialidases. At least one water molecule can fit into the active‐site cavity of this mutant and act as a nucleophile from the face opposite the leaving group (Biochemistry 2003, 42, 12 682). Thus, addition of a CH2 unit (Asp versus Glu) changes the mechanism from inversion back to retention of configuration. Based on Brønsted βlg values, it is proposed that the Y370E mutant reacts by a double‐displacement mechanism (βlg on kcat/Km −0.36±0.04) with Glu370 acting as the nucleophile. However, the Y370F mutant (βlg on kcat/Km −0.79±0.12) reacts via a dissociative transition state. The crystal structure of the Y370F mutant complexed with 2‐deoxy‐2,3‐dehydro‐N‐acetylneuraminic acid shows no significant active‐site perturbation relative to the wild‐type enzyme.

Chemical Insight into the Emergence of Influenza Virus Strains That Are Resistant to Relenza

A reagent panel containing ten 4-substituted 4-nitrophenyl α-D-sialosides and a second panel of the corresponding sialic acid glycals were synthesized and used to probe the inhibition mechanism for two neuraminidases, the N2 enzyme from influenza type A virus and the enzyme from Micromonospora viridifaciens. For the viral enzyme the logarithm of the inhibition constant (Ki) correlated with neither the logarithm of the catalytic efficiency (kcat/Km) nor catalytic proficiency (kcat/Km kun). These linear free energy relationship data support the notion that these inhibitors, which include the therapeutic agent Relenza, are not transition state mimics for the enzyme-catalyzed hydrolysis reaction. Moreover, for the influenza enzyme, a correlation (slope, 0.80 ± 0.08) is observed between the logarithms of the inhibition (Ki) and Michaelis (Km) constants. We conclude that the free energy for Relenza binding to the influenza enzyme mimics the enzyme-substrate interactions at the Michaelis complex. Thus, an influenza mutational response to a 4-substituted sialic acid glycal inhibitor can weaken the interactions between the inhibitor and the viral neuraminidase without a concomitant decrease in free energy of binding for the substrate at the enzyme-catalyzed hydrolysis transition state. The current findings make it clear that new structural motifs and/or substitution patterns need to be developed in the search for a bona fide influenza viral neuraminidase transition state analogue inhibitor.

Bacterial and Viral Sialidases: Contribution of the Conserved Active Site Glutamate to Catalysis

Mutagenesis of the conserved glutamic acid of influenza type A (E277) and Micromonospora viridifaciens (E260) sialidases was performed to probe the contribution of this strictly conserved residue to catalysis. Kinetic studies of the E260D and E260C M. viridifaciens mutant enzymes reveal that the overall mechanism of action has not changed. That is, the mutants are retaining sialidases in which glycosylation and deglycosylation are rate-limiting for k(cat)/K(m) and k(cat), respectively. The solvent kinetic isotope effect and proton inventory on k(cat) for the E260C mutant sialidase provide strong evidence that the newly installed cysteine residue provides little catalytic acceleration. The results are consistent with the conserved aspartic acid residue (D92) becoming the key general acid/base residue in the catalytic cycle. In addition, the E277D mutant influenza type A sialidase is catalytically active toward 4-nitrophenyl α-D-sialoside, although no measurable hydrolysis of natural substrates was observed. Thus, mutating the glutamate residue (E277) to an aspartate increases the activation free energy of hydrolysis for natural substrates by >22 kJ/mol.

Brønsted analysis of an enzyme-catalyzed pseudo-deglycosylation reaction: mechanism of desialylation in sialidases.

The Micromonospora viridifaciens Y370G inverting mutant sialidase has been found to possess beta-sialidase activity with various fluoro-substituted phenyl beta-sialosides. A reagent panel of seven mono- and difluorophenyl beta-d-sialosides was synthesized, and these compounds were used, in conjunction with the parent phenyl beta-d-sialoside, to probe the mechanism of M. viridifaciens Y370G mutant sialidase-catalyzed hydrolyses. These hydrolysis reactions mimic the deglycosylation reaction step of the crucial tyrosinyl enzyme-bound intermediate that is formed during the corresponding wild-type sialidase reactions. The derived Brønsted parameter (beta(lg)) on k(cat)/K(m) is -0.46 +/- 0.02 for the four substrates that display significant activity, and these span a range of leaving group abilities (as judged by the pK(a) of their conjugate acids being between 7.09 and 9.87). The 4-fluoro, 2,3- and 2,5-difluorosubstrates display a diminished activity, whereas the 3,5-difluoro compound undergoes catalyzed hydrolysis exceedingly slowly. These observations, taken with solvent deuterium kinetic isotope effects (k(H(2))(O)/k(D(2))(O)) on the catalyzed hydrolysis of the 2-fluorophenyl substrate of 0.88 +/- 0.24 (k(cat)/K(m)) and 1.16 +/- 0.12 (k(cat)) and the poor inhibition shown by phenol (IC(50) > 1 mM), are consistent with glycosidic C-O cleavage being rate determining for both k(cat)/K(m) and k(cat) with little or no protonation of the departing aryloxide leaving group. The kinetic data reported herein are consistent with rate-limiting glycoside hydrolysis occurring via two distinct transition states that incorporates a nonproductive binding component for the tighter binding substrates.