Stok, Jeanette E.;
Chow, Sharon;
Krenske, Elizabeth H.;
Farfan Soto, Clementina;
Matyas, Csongor;
Poirier, Raymond A.;
Williams, Craig M.;
De Voss, James J.
Direct Observation of an Oxepin from a Bacterial Cytochrome P450‐Catalyzed Oxidation
You can manage bookmarks using lists, please log in to your user account for this.
Media type:
E-Article
Title:
Direct Observation of an Oxepin from a Bacterial Cytochrome P450‐Catalyzed Oxidation
Contributor:
Stok, Jeanette E.;
Chow, Sharon;
Krenske, Elizabeth H.;
Farfan Soto, Clementina;
Matyas, Csongor;
Poirier, Raymond A.;
Williams, Craig M.;
De Voss, James J.
Description:
<jats:title>Abstract</jats:title><jats:p>The cytochromes P450 are hemoproteins that catalyze a range of oxidative C−H functionalization reactions, including aliphatic and aromatic hydroxylation. These transformations are important in a range of biological contexts, including biosynthesis and xenobiotic biodegradation. Much work has been carried out on the mechanism of aliphatic hydroxylation, implicating hydrogen atom abstraction, but aromatic hydroxylation is postulated to proceed differently. One mechanism invokes as the key intermediate an arene oxide (and/or its oxepin tautomer). Conclusive isolation of this intermediate has remained elusive and, currently, direct formation of phenols from a Meisenheimer intermediate is believed to be favored. We report here the identification of a P450 [P450<jats:sub>cam</jats:sub> (CYP101A1) and P450<jats:sub>cin</jats:sub> (CYP176A1)]‐generated arene oxide as a product of in vitro oxidation of <jats:italic>tert</jats:italic>‐butylbenzene. Computations (CBS‐QB3) predict that the arene oxide and oxepin have similar stabilities to other arene oxides/oxepins implicated (but not detected) in P450‐mediated transformations, suggesting that arene oxides can be unstable terminal products of P450‐catalyzed aromatic oxidation that can explain the origin of some observed metabolites.</jats:p>