Litcius/Paper detail

Inverse Solvent Isotope Effects in Enzyme-Catalyzed Reactions

Patrick Fernandez, Andrew S. Murkin

2020Molecules43 citationsDOIOpen Access PDF

Abstract

Solvent isotope effects have long been used as a mechanistic tool for determining enzyme mechanisms. Most commonly, macroscopic rate constants such as kcat and kcat/Km are found to decrease when the reaction is performed in D2O for a variety of reasons including the transfer of protons. Under certain circumstances, these constants are found to increase, in what is termed an inverse solvent kinetic isotope effect (SKIE), which can be a diagnostic mechanistic feature. Generally, these phenomena can be attributed to an inverse solvent equilibrium isotope effect on a rapid equilibrium preceding the rate-limiting step(s). This review surveys inverse SKIEs in enzyme-catalyzed reactions by assessing their underlying origins in common mechanistic themes. Case studies for each category are presented, and the mechanistic implications are put into context. It is hoped that readers may find the illustrative examples valuable in planning and interpreting solvent isotope effect experiments.

Topics & Concepts

Kinetic isotope effectChemistryContext (archaeology)SolventInverseEnzyme kineticsReaction rate constantIsotopeCatalysisLimitingComputational chemistrySolvent effectsReaction rateEnzyme catalysisKineticsThermodynamicsOrganic chemistryActive siteDeuteriumPhysicsMathematicsNuclear physicsPaleontologyBiologyEngineeringQuantum mechanicsMechanical engineeringGeometryChemical Reaction MechanismsPharmacogenetics and Drug MetabolismChemical Reactions and Isotopes
Inverse Solvent Isotope Effects in Enzyme-Catalyzed Reactions | Litcius