Recent advances in quantum mechanical/molecular mechanical calculations of enzyme catalysis: Hydrogen tunnelling in liver alcohol dehydrogenase and inhibition of elastase by α-ketoheterocycles

Gary Tresadern, Paul F. Faulder, M. Paul Gleeson, Zubeir Tai, Grant MacKenzie, Neil A. Burton, Ian H. Hillier

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Hybrid quantum mechanical (QM)/molecular mechanical (MM) calculations are used to study two aspects of enzyme catalysis, Kinetic isotope effects associated with the hydride ion transfer step in the reduction of benzyl alcohol by liver alcohol dehydrogenase are studied by employing variational transition-state theory and optimised multidimensional tunnelling. With the smaller QM region, described at the Hartree-Fock ab initio level, together with a parameterised zinc atom charge, good agreement with experiment is obtained. A comparison is made with the proton transfer in methylamine dehydrogenase. The origin of the large range in pharmacological activity shown by a series of α-ketoheterocycle inhibitors of the serine protease, elastase, is investigated by both force field and QM/MM calculations. Both models point to two different inhibition mechanisms being operative. Initial QM/MM calculations suggest that these are binding, and reaction to form a tetrahedral intermediate, the latter process occurring for only the more potent set of inhibitors.
    Original languageEnglish
    Pages (from-to)108-117
    Number of pages9
    JournalTheoretical Chemistry Accounts
    Volume109
    Issue number3
    DOIs
    Publication statusPublished - 1 Apr 2003

    Keywords

    • Liver alcohol dehydrogenase
    • Methylamine dehydrogenase
    • Quantum mechanical/molecular mechanical methods
    • Tunnelling
    • Variational transition-state theory

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