Catalysis: transition-state molecular recognition?

Summary The key to understanding the fundamental processes of catalysis is the transition state (TS): indeed, catalysis is a transition-state molecular recognition event. Practical objectives, such as the design of TS analogues as potential drugs, or the design of synthetic catalysts (including catalytic antibodies), require prior knowledge of the TS structure to be mimicked. Examples, both old and new, of computational modelling studies are discussed, which illustrate this fundamental concept. It is shown that reactant binding is intrinsically inhibitory, and that attempts to design catalysts that focus simply upon attractive interactions in a binding site may fail. Free-energy changes along the reaction coordinate for SN2 methyl transfer catalysed by the enzyme catechol-O-methyl transferase are described and compared with those for a model reaction in water, as computed by hybrid quantum-mechanical/molecular-mechanical molecular dynamics simulations. The case is discussed of molecular recognition in a xylanase enzyme that stabilises its sugar substrate in a (normally unfavourable) boat conformation and in which a single-atom mutation affects the free-energy of activation dramatically.

[1]  Linus Pauling,et al.  Molecular Architecture and Biological Reactions , 1946 .

[2]  S. Withers,et al.  Sugar ring distortion in the glycosyl-enzyme intermediate of a family G/11 xylanase. , 1999, Biochemistry.

[3]  K N Houk,et al.  Why enzymes are proficient catalysts: beyond the Pauling paradigm. , 2005, Accounts of chemical research.

[4]  M. D. Joshi,et al.  The pKa of the general acid/base carboxyl group of a glycosidase cycles during catalysis: a 13C-NMR study of bacillus circulans xylanase. , 1996, Biochemistry.

[5]  W. Jencks Destabilization is as important as binding , 1993, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.

[6]  R. Schowen,et al.  Transition States of Biochemical Processes , 1978, Springer US.

[7]  R. Schowen,et al.  .alpha.-Deuterium and carbon-13 isotope effects for a simple, intermolecular sulfur-to-oxygen methyl-transfer reaction. Transition-state structures and isotope effects in transmethylation and transalkylation , 1979 .

[8]  宁北芳,et al.  疟原虫var基因转换速率变化导致抗原变异[英]/Paul H, Robert P, Christodoulou Z, et al//Proc Natl Acad Sci U S A , 2005 .

[9]  L. Pauling,et al.  Nature of Forces between Large Molecules of Biological Interest , 1948, Nature.

[10]  R. Borchardt,et al.  .alpha.-Deuterium and carbon-13 isotope effects for methyl transfer catalyzed by catechol O-methyltransferase. SN2-like transition state , 1979 .

[11]  I. Williams,et al.  QM/MM simulations for methyl transfer in solution and catalysed by COMT: ensemble-averaging of kinetic isotope effects. , 2008, Chemical communications.

[12]  R. Rosenfeld Nature , 2009, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[13]  M. Yaguchi,et al.  Mutational and crystallographic analyses of the active site residues of the bacillus circulans xylanase , 1994, Protein science : a publication of the Protein Society.

[14]  Sergio Martí,et al.  Theoretical modeling of enzyme catalytic power: analysis of "cratic" and electrostatic factors in catechol O-methyltransferase. , 2003, Journal of the American Chemical Society.

[15]  I. Williams,et al.  Transition-state structural variation in a model for carbonyl reduction by lactate dehydrogenase : computational validation of empirical predictions based upon Albery-More O'Ferrall-Jencks diagrams , 1992 .

[16]  R. Schowen,et al.  How an enzyme surmounts the activation energy barrier , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[17]  Ian H. Williams,et al.  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. , 2009, Organic & biomolecular chemistry.

[18]  Vicent Moliner,et al.  QM/MM determination of kinetic isotope effects for COMT-catalyzed methyl transfer does not support compression hypothesis. , 2004, Journal of the American Chemical Society.

[19]  W. Jencks Catalysis in chemistry and enzymology , 1969 .

[20]  T. C. Bruice,et al.  A view at the millennium: the efficiency of enzymatic catalysis. , 2002, Accounts of chemical research.

[21]  A. J. Kirby,et al.  Molecular recognition of transition states , 1993, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.

[22]  J. Goodman,et al.  Enzyme catalysis by hydrogen bonds: the balance between transition state binding and substrate binding in oxyanion holes. , 2010, The Journal of organic chemistry.

[23]  F. Young Biochemistry , 1955, The Indian Medical Gazette.

[24]  Mahmoud E S Soliman,et al.  Mechanism of glycoside hydrolysis: A comparative QM/MM molecular dynamics analysis for wild type and Y69F mutant retaining xylanases. , 2009, Organic & biomolecular chemistry.