| Abstract: | Kinetic isotope effects are determined for the enzyme‐catalyzed Claisen rearrangement of chorismate to prephenate using computational methods. The calculated kinetic isotope effects (KIEs) compare reasonably with the few available experimental values with both the theory and experiment obtaining a large KIE for the ether oxygen, indicating large polarization of the transition‐state geometry. Because there is a question of the extent that the experimental rate constants are for chemistry as the rate‐limiting step, the KIEs for all the atoms of the substrate are reported with the exception of the carboxylate groups. A substantial number of large regular and inverse isotope effects are predicted for the hydrogens on the cyclohexadienyl ring related to activation of the reactant and charge reorganization in the transition state. A large KIE is predicted for the hydrogen atom bound to the ether carbon atom because the largest valency change and charge transfer occurs at the ether bond in both the reactant and tansition state. Observation of the overall pattern of predicted KIEs would ensure that conditions are favorable for the rate‐limiting chemistry. © 2003 Wiley Periodicals, Inc. Int J Quantum Chem 94: 287–292, 2003 |
