Computational methods for the study of enzymic reaction mechanisms III: a perturbation plus QM/MM approach for calculating relative free energies of protonation
Date
2005
Authors
Cummins, Peter
Gready, Jill
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Publisher
John Wiley & Sons Inc
Abstract
We describe a coupling parameter, that is, perturbation, approach to effectively create and annihilate atoms in the quantum mechanical Hamiltonian within the closed shell restricted Hartree-Fock formalism. This perturbed quantum mechanical atom (PQA) method is combined with molecular mechanics (MM) methods (PQA/MM) within a molecular dynamics simulation, to model the protein environment (MM region) effects that also make a contribution to the overall free energy change. Using the semiempirical PM3 method to model the QM region, the application of this PQA/MM method is illustrated by calculation of the relative protonation free energy of the conserved OD2 (Asp27) and the N5 (dihydrofolate) proton acceptor sites in the active site of Escherichia coli dihydrofolate reductase (DHFR) with the bound nicotinamide adenine dinucleotide phosphate (NADPH) cofactor. For a number of choices for the QM region, the relative protonation free energy was calculated as the sum of contributions from the QM region and the interaction between the QM and MM regions via the thermodynamic integration (TI) method. The results demonstrate the importance of including the whole substrate molecule in the QM region, and the overall protein (MM) environment in determining the relative stabilities of protonation sites in the enzyme active site. The PQA/MM free energies obtained by TI were also compared with those estimated by a less computationally demanding nonperturbative method based on the linear response approximation (LRA). For some choices of QM region, the total free energies calculated using the LRA method were in very close agreement with the PQA/MM values. However, the QM and QM/MM component free energies were found to differ significantly between the two methods.
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Keywords
Keywords: Approximation theory; Computational methods; Enzymes; Free energy; Molecular dynamics; Perturbation techniques; Substrates; Coupling parameters; Enzyme mechanisms; Hybrid QM/MM; Hydride-ion transfer; Linear response approximation; Protonation free energy; Coupling parameter; Enzyme mechanism; Hybrid QM/MM; Hydride-ion transfer; Linear response approximation; Protonation free energy; Thermodynamic integration
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Source
Journal of Computational Chemistry
Type
Journal article
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2037-12-31