Quantum mechanical methods for enzyme kinetics

Jiali Gao; Donald G. Truhlar

doi:10.1146/annurev.physchem.53.091301.150114

Quantum mechanical methods for enzyme kinetics

Jiali Gao, Donald G. Truhlar

Chemistry (Twin Cities)

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721 Scopus citations

Abstract

This review discusses methods for the incorporation of quantum mechanical effects into enzyme kinetics simulations in which the enzyme is an explicit part of the model. We emphasize three aspects: (a) use of quantum mechanical electronic structure methods such as molecular orbital theory and density functional theory, usually in conjunction with molecular mechanics; (b) treating vibrational motions quantum mechanically, either in an instantaneous harmonic approximation, or by path integrals, or by a three-dimensional wave function coupled to classical nuclear motion; (c) incorporation of multidimensional tunneling approximations into reaction rate calculations.

Original language	English (US)
Pages (from-to)	467-505
Number of pages	39
Journal	Annual Review of Physical Chemistry
Volume	53
DOIs	https://doi.org/10.1146/annurev.physchem.53.091301.150114
State	Published - 2002

Keywords

Catalysis
Dynamics
Free energy
Potential of mean force
QM/MM
Rate constant
Tunneling
Variational transition state theory

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KW - Rate constant

KW - Tunneling

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Quantum mechanical methods for enzyme kinetics

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Keywords

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