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| Author | : Arieh Warshel |
| Publisher | : Wiley-Interscience |
| Total Pages | : 264 |
| Release | : 1991-11-29 |
| Genre | : Computers |
| ISBN | : |
This practical reference explores computer modeling of enzyme reations--techniques that help chemists, biochemists and pharmaceutical researchers understand drug and enzyme action.
| Author | : Jianzhuang Yao |
| Publisher | : |
| Total Pages | : 244 |
| Release | : 2014 |
| Genre | : Autocatalysis |
| ISBN | : |
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.
| Author | : Philip Hanoian |
| Publisher | : |
| Total Pages | : |
| Release | : 2014 |
| Genre | : |
| ISBN | : |
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.
| Author | : Asmit Bhowmick |
| Publisher | : |
| Total Pages | : 110 |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Abstract Understanding and Improving Designed Enzymes by Computer Simulations By Asmit Bhowmick Doctor of Philosophy in Chemical Engineering University of California, Berkeley Professor Teresa Head-Gordon, Chair The ability to control for protein structure, electrostatics and dynamical motions is a fundamental problem that limits our ability to rationally design catalysts for new chemical reactions not known to have a natural biocatalyst. Current computational approaches for de novo enzyme design seek to engineer a small catalytic construct into an accommodating protein scaffold as exemplified by the Rosetta strategy. Here we consider 3 designed enzymes for the Kemp elimination reaction (KE07, KE70 and KE15) that showed minimal catalytic activity. KE07 and KE70 were subsequently improved by 2 orders of magnitude in catalytic efficiency by directed evolution and highlighted the shortcomings of the design process. This work studies two keys issues plaguing the designs - side chain conformational variability and electrostatics. For the first part, a new Monte Carlo sampling method was developed that uses a physical forcefield and coupled with backbone variability and a backbone dependent rotamer library. Using transition state theory with energies/entropies calculated from Monte Carlo simulations, it is shown that in both KE07 and KE70, the initial design was over-optimized to stabilize the enzyme-substrate complex. Mutations introduced by directed evolutions led to destabilization of the enzyme-substrate complex and stabilization of the transition state. Furthermore, analysis of residue correlations via mutual information yielded hotspots, several of which were mutations during directed evolution. Laboratory mutations of these hotspots in the best variant of KE07 led to a drop in catalytic performance, demonstrating their importance. The metrics identified in KE07/KE70 studies were used to predict mutations to improve enzyme KE15 that had not been improved prior to this study. Several mutants, all predicted through computer simulations have now yielded better catalytic activity in the laboratory with the best one 10-fold better than the starting enzyme. In order to quantify the role of electrostatics, a new method was developed using the AMOEBA polarizable forcefield that allowed splitting the contribution of electric field at the substrate by residues and solvent. The improvement in KE07 series could be tracked directly through changes in electric field at the substrate. In comparison, KE70 did not show a significant shift in electrostatic field, suggesting other factors like substrate binding may have been the reason for enhancement of activity. However, the common theme in both enzymes was the lack of participation (and in fact detrimental role) of the scaffold in the reaction. Future design efforts would benefit from an expanded theozyme and careful selection of scaffold based on electrostatic properties. Generating efficient biocatalysts without using laboratory directed evolution would be an inflection point in the field of enzyme design. This work is a step in that direction.
| Author | : Serafin Fraga |
| Publisher | : Springer |
| Total Pages | : 284 |
| Release | : 1995-08-18 |
| Genre | : Science |
| ISBN | : 9783540601333 |
Protein engineering endeavors to design new peptides and proteins or to change the structural and/or functional characteristics of existing ones for specific purposes, opening the way for the development of new drugs. This work develops in a comprehensive way the theoretical formulation for the methods used in computer-assisted modeling and predictions, starting from the basic concepts and proceeding to the more sophisticated methods, such as Monte Carlo and molecular dynamics. An evaluation of the approximations inherent to the simulations will allow the reader to obtain a perspective of the possible deficiencies and difficulties and approach the task with realistic expectations. Examples from the authors laboratories, as well as from the literature provide useful information.
| Author | : Robert H. Rivers |
| Publisher | : |
| Total Pages | : |
| Release | : 1982 |
| Genre | : Enzymes |
| ISBN | : |
| Author | : Inaki Tunon |
| Publisher | : Royal Society of Chemistry |
| Total Pages | : 558 |
| Release | : 2016-11-25 |
| Genre | : Science |
| ISBN | : 1782624295 |
Exploring the theories, methodologies and applications in simulations of enzymatic reactions, this book is a great resource for postgraduate students and researchers.
| Author | : Hernán Alonso |
| Publisher | : |
| Total Pages | : 208 |
| Release | : 2006 |
| Genre | : Chemical reactions |
| ISBN | : |
| Author | : Adrian Mulholland |
| Publisher | : |
| Total Pages | : |
| Release | : 1995 |
| Genre | : |
| ISBN | : |
| Author | : Ali Vessal |
| Publisher | : |
| Total Pages | : 184 |
| Release | : 1984 |
| Genre | : |
| ISBN | : |
