Enzyme-Controlled Nitrogen-Atom Transfer Enables Regiodivergent C−H Amination

We recently demonstrated that variants of cytochrome P450_(BM3) (CYP102A1) catalyze the insertion of nitrogen species into benzylic C–H bonds to form new C–N bonds. An outstanding challenge in the field of C–H amination is catalyst-controlled regioselectivity. Here, we report two engineered variants of P450_(BM3) that provide divergent regioselectivity for C–H amination—one favoring amination of benzylic C–H bonds and the other favoring homo-benzylic C–H bonds. The two variants provide nearly identical kinetic isotope effect values (2.8–3.0), suggesting that C–H abstraction is rate-limiting. The 2.66-Å crystal structure of the most active enzyme suggests that the engineered active site can preorganize the substrate for reactivity. We hypothesize that the enzyme controls regioselectivity through localization of a single C–H bond close to the iron nitrenoid