Xinyun Zhao scite author profile

Microsomal prostaglandin E synthase-1 (mPGES-1) is an inducible prostaglandin E synthase after exposure to pro-inflammatory stimuli and, therefore, represents a novel target for therapeutic treatment of acute and chronic inflammatory disorders. It is essential to identify mPGES-1 inhibitors with novel scaffolds as new leads or hits for the purpose of drug design and discovery that aim to develop the next-generation anti-inflammatory drugs. Herein we report novel mPGES-1 inhibitors identified through a combination of large-scale structure-based virtual screening, flexible docking, molecular dynamics simulations, binding free energy calculations, and in vitro assays on the actual inhibitory activity of the computationally selected compounds. The computational studies are based on our recently developed three-dimensional (3D) structural model of mPGES-1 in its open state. The combined computational and experimental studies have led to identification of new mPGES-1 inhibitors with new scaffolds. In particular, (Z)-5-benzylidene-2-iminothiazolidin-4-one is a promising novel scaffold for the further rational design and discovery of new mPGES-1 inhibitors. To our best knowledge, this is the first time a 3D structural model of the open-state mPGES-1 is used in structure-based virtual screening of a large library of available compounds for the mPGES-1 inhibitor identification. The positive experimental results suggest that our recently modeled trimeric structure of mPGES-1 in its open state is ready for the structure-based drug design and discovery.

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Fundamental Reaction Pathway and Free Energy Profile for Hydrolysis of Intracellular Second Messenger Adenosine 3′,5′-Cyclic Monophosphate (cAMP) Catalyzed by Phosphodiesterase-4

Chen

Zhao

Xiong

et al. 2011

J. Phys. Chem. B

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As important drug targets for a variety of human diseases, cyclic nucleotide phosphodiesterases (PDEs) are a superfamily of enzymes sharing a similar catalytic site. We have performed pseudobond first-principles quantum mechanical/molecular mechanical-free energy perturbation (QM/MM-FE) and QM/MM-Poisson-Boltzmann surface area (PBSA) calculations to uncover the detailed reaction mechanism for PDE4-catalyzed hydrolysis of adenosine 3',5'-cyclic monophosphate (cAMP). This is the first report on QM/MM reaction-coordinate calculations including the protein environment of any PDE-catalyzed reaction system, demonstrating a unique catalytic reaction mechanism. The QM/MM-FE and QM/MM-PBSA calculations revealed that the PDE4-catalyzed hydrolysis of cAMP consists of two reaction stages: cAMP hydrolysis (stage 1) and bridging hydroxide ion regeneration (stage 2). The stage 1 includes the binding of cAMP in the active site, nucleophilic attack of the bridging hydroxide ion on the phosphorous atom of cAMP, cleavage of O3'-P phosphoesteric bond of cAMP, protonation of the departing O3' atom, and dissociation of hydrolysis product (AMP). The stage 2 includes the binding of solvent water molecules with the metal ions in the active site and regeneration of the bridging hydroxide ion. The dissociation of the hydrolysis product is found to be rate-determining for the enzymatic reaction process. The calculated activation Gibbs free energy of ≥16.0 and reaction free energy of -11.1 kcal/mol are in good agreement with the experimentally derived activation free energy of 16.6 kcal/mol and reaction free energy of -11.5 kcal/mol, suggesting that the catalytic mechanism obtained from this study is reliable and provides a solid base for future rational drug design.

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Reaction Mechanism for Cocaine Esterase-Catalyzed Hydrolyses of (+)- and (−)-Cocaine: Unexpected Common Rate-Determining Step

et al. 2011

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First-principles quantum mechanical/molecular mechanical (QM/MM)-free energy (FE) calculations have been performed to examine catalytic mechanism for cocaine esterase (CocE)-catalyzed hydrolysis of (+)-cocaine in comparison with CocE-catalyzed hydrolysis of (−)-cocaine. It has been shown that the acylation of (+)-cocaine consists of nucleophilic attack of hydroxyl group of Ser117 on carbonyl carbon of (+)-cocaine benzoyl ester and the dissociation of (+)-cocaine benzoyl ester. The first reaction step of deacylation of (+)-cocaine, which is identical to that of (−)-cocaine, is rate-determining, indicating that CocE-catalyzed hydrolyses of (+)- and (−)-cocaine have a common rate-determining step. The computational results predict that the catalytic rate constant of CocE against (+)-cocaine should be the same as that of CocE against (−)-cocaine, in contrast with the remarkable difference between human butyrylcholinesterase-catalyzed hydrolyses of (+)- and (−)-cocaine. The prediction has been confirmed by experimental kinetic analysis on CocE-catalyzed hydrolysis of (+)-cocaine in comparison with CocE-catalyzed hydrolysis of (−)-cocaine. The determined common rate-determining step indicates that rational design of a high-activity mutant of CocE should be focused on the first reaction step of the deacylation. Further, the obtained mechanistic insights into the detailed differences in the acylation between the (+)- and (−)-cocaine hydrolyses provide indirect clues for rational design of amino acid mutations that could more favorably stabilize the rate-determining transition state in the deacylation and, thus, improve the catalytic activity of CocE. This study provides a valuable mechanistic base for rational design of an improved esterase for therapeutic treatment of cocaine abuse.

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Cocaine Esterase–Cocaine Binding Process and the Free Energy Profiles by Molecular Dynamics and Potential of Mean Force Simulations

et al. 2012

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The combined molecular dynamics (MD) and potential of mean force (PMF) simulations have been performed to determine the free energy profiles for the binding process of (−)-cocaine interacting with wild-type cocaine esterase (CocE) and its mutants (T172R/G173Q and L119A/L169K/G173Q). According to the MD simulations, the general protein-(−)-cocaine binding mode is not affected by the mutations, e.g. the benzoyl group of (−)-cocaine is always bound in a sub-site composed of aromatic residues W151, W166, F261, and F408 and hydrophobic residue L407, while the carbonyl oxygen on the benzoyl group of (−)-cocaine is hydrogen-bonded with the oxyanion-hole residues Y44 and Y118. According to the PMF-calculated free energy profiles for the binding process, the binding free energies for (−)-cocaine with the wild-type, T172R/G173Q, and L119A/L169K/G173Q CocEs are predicted to be −6.4, −6.2, and −5.0 kcal/mol, respectively. The computational predictions are supported by experimental kinetic data, as the calculated binding free energies are in good agreement with the experimentally-derived binding free energies, i.e. −7.2, −6.7, and −4.8 kcal/mol for the wild-type, T172R/G173Q, and L119A/L169K/G173Q, respectively. The reasonable agreement between the computational and experimental data suggests that the PMF simulations may be used as a valuable tool in new CocE mutant design that aims to decrease the Michaelis-Menten constant of the enzyme for (−)-cocaine.

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Xinyun Zhao

Novel human mPGES-1 inhibitors identified through structure-based virtual screening

Fundamental Reaction Pathway and Free Energy Profile for Hydrolysis of Intracellular Second Messenger Adenosine 3′,5′-Cyclic Monophosphate (cAMP) Catalyzed by Phosphodiesterase-4

Reaction Mechanism for Cocaine Esterase-Catalyzed Hydrolyses of (+)- and (−)-Cocaine: Unexpected Common Rate-Determining Step

Cocaine Esterase–Cocaine Binding Process and the Free Energy Profiles by Molecular Dynamics and Potential of Mean Force Simulations

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