Ian R. Greig scite author profile

O-GlcNAcase catalyzes the cleavage of beta-O-linked 2-acetamido-2-deoxy-beta-d-glucopyranoside (O-GlcNAc) from serine and threonine residues of post-translationally modified proteins. Two potent inhibitors of this enzyme are O-(2-acetamido-2-deoxy-d-glucopyranosylidene)amino-N-phenylcarbamate (PUGNAc) and 1,2-dideoxy-2'-methyl-alpha-d-glucopyranoso[2,1-d]-Delta2'-thiazoline (NAG-thiazoline). Derivatives of these inhibitors differ in their selectivity for human O-GlcNAcase over the functionally related human lysosomal beta-hexosamindases, with PUGNAc derivatives showing modest selectivities and NAG-thiazoline derivatives showing high selectivities. The molecular basis for this difference in selectivities is addressed as is how well these inhibitors mimic the O-GlcNAcase-stabilized transition state (TS). Using a series of substrates, ground state (GS) inhibitors, and transition state mimics having analogous structural variations, we describe linear free energy relationships of log(KM/kcat) versus log(KI) for PUGNAc and NAG-thiazoline. These relationships suggest that PUGNAc is a poor transition state analogue, while NAG-thiazoline is revealed as a transition state mimic. Comparative X-ray crystallographic analyses of enzyme-inhibitor complexes reveal subtle molecular differences accounting for the differences in selectivities between these two inhibitors and illustrate key molecular interactions. Computational modeling of species along the reaction coordinate, as well as PUGNAc and NAG-thiazoline, provide insight into the features of NAG-thiazoline that resemble the transition state and reveal where PUGNAc fails to capture significant binding energy. These studies also point to late transition state poise for the O-GlcNAcase catalyzed reaction with significant nucleophilic participation and little involvement of the leaving group. The potency of NAG-thiazoline, its transition state mimicry, and its lack of traditional transition state-like design features suggest that potent rationally designed glycosidase inhibitors can be developed that exploit variation in transition state poise.

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Tuning Mechanism‐Based Inactivators of Neuraminidases: Mechanistic and Structural Insights

Buchini

Gallat

Greig

et al. 2014

Angew Chem Int Ed

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3-Fluorosialosyl fluorides are inhibitors of sialidases that function by the formation of a long-lived covalent active-site adduct and have potential as therapeutics if made specific for the pathogen sialidase. Surprisingly, human Neu2 and the Trypanosoma cruzi trans-sialidase are inactivated more rapidly by the reagent with an equatorial fluorine at C3 than by its axial epimer, with reactivation following the same pattern. To explore a possible stereoelectronic basis for this, rate constants for spontaneous hydrolysis of the full series of four 3-fluorosialosyl fluorides were measured, and ground-state energies for each computed. The alpha (equatorial) anomeric fluorides hydrolyze more rapidly than their beta anomers, consistent with their higher ground-state energies. However ground-state energies do not explain the relative spontaneous reactivities of the 3-fluoro-epimers. The three-dimensional structures of the two 3-fluoro-sialosyl enzyme intermediates of human Neu2 were solved, revealing key stabilizing interactions between Arg21 and the equatorial, but not the axial, fluorine. Because of changes in geometry these interactions will increase at the transition state, likely explaining the difference in reaction rates.

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Elucidating the Nature of theStreptomyces plicatusβ-Hexosaminidase-Bound Intermediate Using ab initio Molecular Dynamics Simulations

Greig¹,

Zahariev²,

Withers³

2008

J. Am. Chem. Soc.

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By using all-atom ab initio molecular dynamics simulations, the solution pK(a) of the oxazolinium ion intermediate formed during the Streptomyces plicatus beta-hexosaminidase (SpHex)-catalyzed hydrolysis of beta-D-N-acetylglucosaminides is estimated as pK(a) = 7.7. The structure and protonation state of the enzyme-bound intermediate have also been investigated, using hybrid QM/MM methods. The protonation state and conformational properties of the enzyme bound intermediate are found to be sensitive to the protonation state of a number of ionisable residues (other than the aspartate-glutamate catalytic dyad) suggesting that the microscopic electrostatic environment of SpHex not only perturbs the relative magnitudes of the pK(a) values of the Asp side chain carboxylate and oxazolinium ion but also that SpHex binds its intermediate in a distorted conformation with respect to its ground-state conformation in solution.

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Computational mutagenesis reveals the role of active-site tyrosine in stabilising a boat conformation for the substrate: QM/MM molecular dynamics studies of wild-type and mutant xylanases

et al. 2009

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Molecular dynamics simulations have been performed for non-covalent complexes of phenyl beta-xylobioside with the retaining endo-beta-1,4-xylanase from B. circulans (BCX) and its Tyr69Phe mutant using a hybrid QM/MM methodology. A trajectory initiated for the wild-type enzyme-substrate complex with the proximal xylose ring bound at the -1 subsite (adjacent to the scissile glycosidic bond) in the (4)C(1) chair conformation shows spontaneous transformation to the (2,5)B boat conformation, and potential of mean force calculations indicate that the boat is approximately 30 kJ mol(-1) lower in free energy than the chair. Analogous simulations for the mutant lacking one oxygen atom confirm the key role of Tyr69 in stabilizing the boat in preference to the (4)C(1) chair conformation, with a relative free energy difference of about 20 kJ mol(-1), by donating a hydrogen bond to the endocyclic oxygen of the proximal xylose ring. QM/MM MD simulations for phenyl beta-xyloside in water, with and without a propionate/propionic acid pair to mimic the catalytic glutamate/glutamic acid pair of the enzyme, show the (4)C(1) chair to be stable, although a hydrogen bond between the OH group at C2 of xylose and the propionate moiety seems to provide some stabilization for the (2,5)B conformation.

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Probing Synergy between Two Catalytic Strategies in the Glycoside Hydrolase O-GlcNAcase Using Multiple Linear Free Energy Relationships

et al. 2009

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Human O-GlcNAcase plays an important role in regulating the post-translational modification of serine and threonine residues with beta-O-linked N-acetylglucosamine monosaccharide unit (O-GlcNAc). The mechanism of O-GlcNAcase involves nucleophilic participation of the 2-acetamido group of the substrate to displace a glycosidically linked leaving group. The tolerance of this enzyme for variation in substrate structure has enabled us to characterize O-GlcNAcase transition states using several series of substrates to generate multiple simultaneous free-energy relationships. Patterns revealing changes in mechanism, transition state, and rate-determining step upon concomitant variation of both nucleophilic strength and leaving group abilities are observed. The observed changes in mechanism reflect the roles played by the enzymic general acid and the catalytic nucleophile. Significantly, these results illustrate how the enzyme synergistically harnesses both modes of catalysis; a feature that eludes many small molecule models of catalysis. These studies also suggest the kinetic significance of an oxocarbenium ion intermediate in the O-GlcNAcase-catalyzed hydrolysis of glucosaminides, probing the limits of what may be learned using nonatomistic investigations of enzymic transition-state structure and offering general insights into how the superfamily of retaining glycoside hydrolases act as efficient catalysts.

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Ian R. Greig

Analysis of PUGNAc and NAG-thiazoline as Transition State Analogues for Human O-GlcNAcase: Mechanistic and Structural Insights into Inhibitor Selectivity and Transition State Poise

Tuning Mechanism‐Based Inactivators of Neuraminidases: Mechanistic and Structural Insights

Elucidating the Nature of theStreptomyces plicatusβ-Hexosaminidase-Bound Intermediate Using ab initio Molecular Dynamics Simulations

Computational mutagenesis reveals the role of active-site tyrosine in stabilising a boat conformation for the substrate: QM/MM molecular dynamics studies of wild-type and mutant xylanases

Probing Synergy between Two Catalytic Strategies in the Glycoside Hydrolase O-GlcNAcase Using Multiple Linear Free Energy Relationships

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