Enantioselective Benzylic Hydroxylation Catalysed by P450 Monooxygenases: Characterisation of a P450cam Mutant Library and Molecular Modelling

Anja Eichler; Ł, Gricman; Susanne Herter; Paul Kelly; Nicholas Turner; Jurgen Pleiss; Sabine Flitsch

doi:10.1002/cbic.201500536

Enantioselective Benzylic Hydroxylation Catalysed by P450 Monooxygenases: Characterisation of a P450cam Mutant Library and Molecular Modelling

Anja Eichler, Ł, Gricman, Susanne Herter, Paul Kelly, Nicholas Turner, Jurgen Pleiss, Sabine Flitsch

Research output: Contribution to journal › Article › peer-review

Abstract

Cytochrome P450 monooxygenases can catalyse the stereoselective C−H activation of a very broad range of substrates. Prediction and control of enantioselectivity of this enzyme class is of great interest for the synthesis of high-value chiral molecules. Here we have used a combination of molecular dynamics simulations and experimental screening to study the enantioselectivity of a library of active-site mutants of chimeric P450cam-RhFRed towards the benzylic hydroxylation of structurally related regioisomers of ethylmethylbenzene. Small variations either in substrate structure or in enzyme active site architecture were shown to lead to dramatic changes in enantioselectivity; this was broadly in agreement with computational predictions. In addition to validating computational approaches, these studies have provided us with a deeper understanding of effects that might control stereoselectivity in these biooxidation reactions.

Original language	English
Pages (from-to)	426-432
Number of pages	7
Journal	CHEMBIOCHEM
Volume	17
Issue number	5
Early online date	2 Mar 2016
DOIs	https://doi.org/10.1002/cbic.201500536
Publication status	Published - 2 Mar 2016

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abstract = "Cytochrome P450 monooxygenases can catalyse the stereoselective C−H activation of a very broad range of substrates. Prediction and control of enantioselectivity of this enzyme class is of great interest for the synthesis of high-value chiral molecules. Here we have used a combination of molecular dynamics simulations and experimental screening to study the enantioselectivity of a library of active-site mutants of chimeric P450cam-RhFRed towards the benzylic hydroxylation of structurally related regioisomers of ethylmethylbenzene. Small variations either in substrate structure or in enzyme active site architecture were shown to lead to dramatic changes in enantioselectivity; this was broadly in agreement with computational predictions. In addition to validating computational approaches, these studies have provided us with a deeper understanding of effects that might control stereoselectivity in these biooxidation reactions.",

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AU - Eichler, Anja

AU - Gricman, Ł,

AU - Herter, Susanne

AU - Kelly, Paul

AU - Turner, Nicholas

AU - Pleiss, Jurgen

AU - Flitsch, Sabine

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N2 - Cytochrome P450 monooxygenases can catalyse the stereoselective C−H activation of a very broad range of substrates. Prediction and control of enantioselectivity of this enzyme class is of great interest for the synthesis of high-value chiral molecules. Here we have used a combination of molecular dynamics simulations and experimental screening to study the enantioselectivity of a library of active-site mutants of chimeric P450cam-RhFRed towards the benzylic hydroxylation of structurally related regioisomers of ethylmethylbenzene. Small variations either in substrate structure or in enzyme active site architecture were shown to lead to dramatic changes in enantioselectivity; this was broadly in agreement with computational predictions. In addition to validating computational approaches, these studies have provided us with a deeper understanding of effects that might control stereoselectivity in these biooxidation reactions.

AB - Cytochrome P450 monooxygenases can catalyse the stereoselective C−H activation of a very broad range of substrates. Prediction and control of enantioselectivity of this enzyme class is of great interest for the synthesis of high-value chiral molecules. Here we have used a combination of molecular dynamics simulations and experimental screening to study the enantioselectivity of a library of active-site mutants of chimeric P450cam-RhFRed towards the benzylic hydroxylation of structurally related regioisomers of ethylmethylbenzene. Small variations either in substrate structure or in enzyme active site architecture were shown to lead to dramatic changes in enantioselectivity; this was broadly in agreement with computational predictions. In addition to validating computational approaches, these studies have provided us with a deeper understanding of effects that might control stereoselectivity in these biooxidation reactions.

U2 - 10.1002/cbic.201500536

DO - 10.1002/cbic.201500536

M3 - Article

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Enantioselective Benzylic Hydroxylation Catalysed by P450 Monooxygenases: Characterisation of a P450cam Mutant Library and Molecular Modelling

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