Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study

Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study

There are two types of cytochrome P450 enzymes in nature, namely, the monooxygenases and the peroxygenases. Both enzyme classes participate in substrate biodegradation or biosynthesis reactions in nature, but the P450 monooxygenases use dioxygen, while the peroxygenases take H<sub>2</sub>...

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Main Authors: Yen-Ting Lin, Sam P. de Visser
Format: Article
Language:English
Published: MDPI AG 2021-07-01
Series:International Journal of Molecular Sciences
Subjects:
biocatalysis
enzyme mechanism
cytochrome P450
hydroxylation
desaturation
biofuel
Online Access:https://www.mdpi.com/1422-0067/22/13/7172
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spelling doaj-357a9c7261dc43d1993f734de0b0c39f2021-07-15T15:38:22ZengMDPI AGInternational Journal of Molecular Sciences1661-65961422-00672021-07-01227172717210.3390/ijms22137172Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational StudyYen-Ting Lin0Sam P. de Visser1Manchester Institute of Biotechnology, The University of Manchester, Manchester M1 7DN, UKManchester Institute of Biotechnology, The University of Manchester, Manchester M1 7DN, UKThere are two types of cytochrome P450 enzymes in nature, namely, the monooxygenases and the peroxygenases. Both enzyme classes participate in substrate biodegradation or biosynthesis reactions in nature, but the P450 monooxygenases use dioxygen, while the peroxygenases take H<sub>2</sub>O<sub>2</sub> in their catalytic cycle instead. By contrast to the P450 monooxygenases, the P450 peroxygenases do not require an external redox partner to deliver electrons during the catalytic cycle, and also no external proton source is needed. Therefore, they are fully self-sufficient, which affords them opportunities in biotechnological applications. One specific P450 peroxygenase, namely, P450 OleT<sub>JE</sub>, reacts with long-chain linear fatty acids through oxidative decarboxylation to form hydrocarbons and, as such, has been implicated as a suitable source for the biosynthesis of biofuels. Unfortunately, the reactions were shown to produce a considerable amount of side products originating from C<sup>α</sup> and C<sup>β</sup> hydroxylation and desaturation. These product distributions were found to be strongly dependent on whether the substrate had substituents on the C<sup>α</sup> and/or C<sup>β</sup> atoms. To understand the bifurcation pathways of substrate activation by P450 OleT<sub>JE</sub> leading to decarboxylation, C<sup>α</sup> hydroxylation, C<sup>β</sup> hydroxylation and C<sup>α</sup>−C<sup>β</sup> desaturation, we performed a computational study using 3-phenylpropionate and 2-phenylbutyrate as substrates. We set up large cluster models containing the heme, the substrate and the key features of the substrate binding pocket and calculated (using density functional theory) the pathways leading to the four possible products. This work predicts that the two substrates will react with different reaction rates due to accessibility differences of the substrates to the active oxidant, and, as a consequence, these two substrates will also generate different products. This work explains how the substrate binding pocket of P450 OleT<sub>JE</sub> guides a reaction to a chemoselectivity.https://www.mdpi.com/1422-0067/22/13/7172biocatalysisenzyme mechanismcytochrome P450hydroxylationdesaturationbiofuel
collection DOAJ
language English
format Article
sources DOAJ
author Yen-Ting Lin
Sam P. de Visser
spellingShingle Yen-Ting Lin
Sam P. de Visser
Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study
International Journal of Molecular Sciences
biocatalysis
enzyme mechanism
cytochrome P450
hydroxylation
desaturation
biofuel
author_facet Yen-Ting Lin
Sam P. de Visser
author_sort Yen-Ting Lin
title Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study
title_short Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study
title_full Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study
title_fullStr Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study
title_full_unstemmed Product Distributions of Cytochrome P450 OleT<sub>JE</sub> with Phenyl-Substituted Fatty Acids: A Computational Study
title_sort product distributions of cytochrome p450 olet<sub>je</sub> with phenyl-substituted fatty acids: a computational study
publisher MDPI AG
series International Journal of Molecular Sciences
issn 1661-6596
1422-0067
publishDate 2021-07-01
description There are two types of cytochrome P450 enzymes in nature, namely, the monooxygenases and the peroxygenases. Both enzyme classes participate in substrate biodegradation or biosynthesis reactions in nature, but the P450 monooxygenases use dioxygen, while the peroxygenases take H<sub>2</sub>O<sub>2</sub> in their catalytic cycle instead. By contrast to the P450 monooxygenases, the P450 peroxygenases do not require an external redox partner to deliver electrons during the catalytic cycle, and also no external proton source is needed. Therefore, they are fully self-sufficient, which affords them opportunities in biotechnological applications. One specific P450 peroxygenase, namely, P450 OleT<sub>JE</sub>, reacts with long-chain linear fatty acids through oxidative decarboxylation to form hydrocarbons and, as such, has been implicated as a suitable source for the biosynthesis of biofuels. Unfortunately, the reactions were shown to produce a considerable amount of side products originating from C<sup>α</sup> and C<sup>β</sup> hydroxylation and desaturation. These product distributions were found to be strongly dependent on whether the substrate had substituents on the C<sup>α</sup> and/or C<sup>β</sup> atoms. To understand the bifurcation pathways of substrate activation by P450 OleT<sub>JE</sub> leading to decarboxylation, C<sup>α</sup> hydroxylation, C<sup>β</sup> hydroxylation and C<sup>α</sup>−C<sup>β</sup> desaturation, we performed a computational study using 3-phenylpropionate and 2-phenylbutyrate as substrates. We set up large cluster models containing the heme, the substrate and the key features of the substrate binding pocket and calculated (using density functional theory) the pathways leading to the four possible products. This work predicts that the two substrates will react with different reaction rates due to accessibility differences of the substrates to the active oxidant, and, as a consequence, these two substrates will also generate different products. This work explains how the substrate binding pocket of P450 OleT<sub>JE</sub> guides a reaction to a chemoselectivity.
topic biocatalysis
enzyme mechanism
cytochrome P450
hydroxylation
desaturation
biofuel
url https://www.mdpi.com/1422-0067/22/13/7172
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AT sampdevisser productdistributionsofcytochromep450oletsubjesubwithphenylsubstitutedfattyacidsacomputationalstudy
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