Simulating Enzyme Reactivity
Simulating Enzyme Reactivity

Author: Inaki Tunon

Publisher: Royal Society of Chemistry

Published: 2016-11-16

Total Pages: 558

ISBN-13: 1782626832

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The simulation of enzymatic processes is a well-established field within computational chemistry, as demonstrated by the 2013 Nobel Prize in Chemistry. It has been attracting increasing attention in recent years due to the potential applications in the development of new drugs or new environmental-friendly catalysts. Featuring contributions from renowned authors, including Nobel Laureate Arieh Warshel, this book explores the theories, methodologies and applications in simulations of enzyme reactions. It is the first book offering a comprehensive perspective of the field by examining several different methodological approaches and discussing their applicability and limitations. The book provides the basic knowledge for postgraduate students and researchers in chemistry, biochemistry and biophysics, who want a deeper understanding of complex biological process at the molecular level.

Dynamic Analysis of Enzyme Systems
Dynamic Analysis of Enzyme Systems

Author: Katsuya Hayashi

Publisher: Springer

Published: 1986-02

Total Pages: 392

ISBN-13:

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This book is concerned with a quantitative analysis of dynamic behavior of various enzymatic reaction systems by computer simulation. The authors and coworkers have been engaged in cooperative research since 1975, seeking to clarify the catalytic and regulatory characteristics of enzymatic reactions in vivo and control mechanisms suitable for enzyme technology. Rather than "enzyme kinetics" generally known in enzymol· ogy, this research has employed an approach called "enzyme dynamics" which concentrates on the exact schematic representation of an actual reac tion mechanism, derivation of rate equation on the basis of the scheme, and computer simulation of its dynamic behavior (numerical solution of the rate equation and explanation of kinetic and regulatory properties of the enzymatic reaction). A rate equation representing the behavior of enzymatic reactions is gen erally expressed by a set of nonlinear differential equations. The analytic solution of rate equations is therefore impossible in general, making it necessary to introduce some approximations in order to analyze the exper· imental data in enzyme kinetics. For example, under an assumption of excess substrate against enzyme in a closed system, we commonly use the linear approximation for the early period of reaction, the quasi-steady state approximation based on putative maintenance of steady state in en zyme species, and the rapid-equilibrium approximation assuming instantane ous equilibration in complex formation and between complexes. The kinetic characteristics obtained by these approximations do not always reflect the dynamic behavior of actual enzymatic reactions.

Understanding Enzyme Catalysis Using Computer Simulation
Understanding Enzyme Catalysis Using Computer Simulation

Author:

Publisher:

Published: 2010

Total Pages:

ISBN-13:

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Enzymes catalyze biochemical reactions with remarkable specificity and efficiency, usually under physiological conditions. Computer simulation is a powerful tool for understanding enzyme catalytic mechanisms, particularly in cases where standard experimental techniques may be of limited utility. Here, we present an overview of the application of computer simulation techniques to understanding enzyme catalytic mechanisms. Examples using quantum chemical methods, as well as combined quantum mechanical/classical mechanical approaches, are provided.

Computer Simulations of Enzymes
Computer Simulations of Enzymes

Author: Jianzhuang Yao

Publisher:

Published: 2014

Total Pages: 244

ISBN-13:

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Enzymes are important catalysts in living systems, and understanding catalytic mechanisms of enzymes is an important task for modern biophysics and biochemistry. Computer simulations have emerged as very useful tools for understanding how enzymes work. In this dissertation, QM/MM MD simulations were applied to study the catalytic mechanisms of several enzymes, including sedolisin, S-adenosyl-L-methionine (AdoMet)-dependent methyltransferases, and salicylic acid binding protein 2. For sedolisin, we focus on the acylation and deacylation reactions catalyzed by the enzymes. We proposed a general acid/base mechanism involving the Glu/Asp residues at the active site. MD and QM/MM free energy simulations on pro-kumamolisin show that the protonation of Asp164 would be able to trigger conformational changes and generate the functional active site for autocatalysis. The free energy simulations reported for SAMT, an AdoMet-dependent methyltransferase, showed that while the structure of the reactant complex containing salicylate, its natural substrate, is rather close to the corresponding TS structure, this is not the case for 4-hydroxybenzoate. The simulations demonstrated that additional energy is required to generate the TS-like structure for 4-hydroxybenzoate, consistent with the low activity of the enzyme toward this substrate. For protein lysine methyltransferase SET7/9, we showed that while the wild type SET7/9 may act like a mono-methylase, the Y245→A mutation could increase the ability of SET7/9 to add two more methyl groups on the target lysine. The substrate specificity of salicylic acid binding protein 2 (SABP2) has also been studied during my graduate study. This enzyme has promiscuous esterase activity toward a series of substrates, but shows high activity toward its natural substrate methyl salicylate (MeSA). We demonstrated that SABP2 seems to represent a case in which the enzyme itself might have not been perfectly evolved and that substrate-assisted catalysis (SAC) involving its natural substrate may be used to enhance the activity and achieve substrate discrimination. In addition to enzymes, the prediction of protein-protein interactions (PPI) is also included in my dissertation. We established a robust pipeline for PPI prediction by integrating multiple classifiers using random forests algorithm. This pipeline could be very useful for predicting PPI.

Computer Simulations Of Enzymes
Computer Simulations Of Enzymes

Author: Philip Hanoian

Publisher:

Published: 2014

Total Pages:

ISBN-13:

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Enzymes are proteins that perform the essential function of facilitating chemical reactions within living organisms, and the rate enhancements provided by enzymes are so significant that they remain a marvel for chemists today. The study of enzymes is thus pervaded by attempts to understand the precise mechanisms by which enzymes achieve these rate enhancements, with additional focus on the impressive level of specificity and selectivity these protein catalysts display as well. In this thesis, four studies on enzymatic systems are presented with the goal of further elucidating the mechanisms by which enzymes confer enormous rate enhancements to chemical reactions. In the first study, mixed quantum mechanical/molecular mechanical calculations are applied to study a series of phenolate inhibitors of increasing pKa bound to ketosteroid isomerase to explore the catalytically relevant hydrogen bonds in the enzyme active site. The second study uses molecular dynamics simulations to explore the use of water in the active site in lieu of the native enzymatic hydrogen bonds. The third study focuses on the positioning of the catalytic base in ketosteroid isomerase using molecular dynamics simulations, and this positioning is suggested to arise from non-local contributions involving nearby hydrophobic residues and an active site loop. In the final study, an additional enzyme, dihydrofolate reductase is examined, and empirical valence bond molecular dynamics simulations are applied to evaluate the free energy barriers of the wild-type enzyme and several evolutionarily motivated mutants. Overall, these studies help to further our understanding of enzymes and the roles of individual factors in enzyme catalysis.