Multi-State Epoxidation of Ethene by Cytochrome P450:  A Quantum Chemical Study

The epoxidation of ethene by a model for Compound I of cytochrome P450, studied by the use of density functional B3LYP calculations, involves two-state reactivity (TSR) with multiple electromer species, hence “multi-state epoxidation”. The reaction is found to proceed in stepwise and effectively con...

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Bibliographic Details
Published in:Journal of the American Chemical Society 2001-04, Vol.123 (13), p.3037-3047
Main Authors: de Visser, Sam P, Ogliaro, François, Harris, Nathan, Shaik, Sason
Format: Article
Language:English
Subjects:
Cytochrome P-450 Enzyme System - chemistry
Epoxy Compounds - chemistry
Ethylenes - chemistry
Free Radicals - chemistry
Isomerism
Models, Chemical
Optical Rotation
Quantum Theory
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Summary:The epoxidation of ethene by a model for Compound I of cytochrome P450, studied by the use of density functional B3LYP calculations, involves two-state reactivity (TSR) with multiple electromer species, hence “multi-state epoxidation”. The reaction is found to proceed in stepwise and effectively concerted manners. Several reactive states are involved; the reactant is an (oxo)iron(IV) porphyrin cation radical complex with two closely lying spin states (quartet and doublet), both of which react with ethene to form intermediate complexes with a covalent C−O bond and a carbon-centered radical (radical intermediates). The radical intermediates exist in two electromers that differ in the oxidation state of iron; Por+•FeIIIOCH2CH2 • and PorFeIVOCH2CH2 • (Por = porphyrin). These radical intermediates exist in both the doublet- and quartet spin states. The quartet spin intermediates have substantial barriers for transformation to the quartet spin PorFeIII−epoxide complex (2.3 kcal mol-1 for PorFeIVOCH2CH2 • and 7.2 kcal mol-1 for Por+•FeIIIOCH2CH2 •). In contrast, the doublet spin radicals collapse to the corresponding PorFeIII−epoxide complex with virtually no barriers. Consequently, the lifetimes of the radical intermediates are much longer on the quartet- than on the doublet spin surface. The loss of isomeric identity in the epoxide and rearrangements to other products arise therefore mostly, if not only, from the quartet process, while the doublet state epoxidation is effectively concerted (Scheme 7). Experimental trends are discussed in the light of the computed mechanistic scheme, and a comparison is made with closely related mechanistic schemes deduced from experiment.
ISSN:0002-7863
1520-5126
DOI:10.1021/ja003544+