Efficient biocatalytic C-H bond oxidation: an engineered heme-thiolate peroxygenase from a thermostable cytochrome P450.

A highly sought after reaction in chemical synthesis is the activation of unactivated carbon-hydrogen bonds. We demonstrate the hydroxylation of fatty acids using an engineered thermostable archaeal cytochrome P450 enzyme. By replacing a seven amino acid section of the I-helix, the nicotinamide cofactor-dependent monooxygenase was converted into a hydrogen peroxide using peroxygenase, enabling the efficient biocatalytic oxidation of C-H bonds at room temperature to 90 °C.

Selective Oxidations Using a Cytochrome P450 Enzyme Variant Driven with Surrogate Oxygen Donors and Light.

Cytochrome P450 monooxygenase enzymes are versatile catalysts, which have been adapted for multiple applications in chemical synthesis. Mutation of a highly conserved active site threonine to a glutamate can convert these enzymes into peroxygenases that utilise hydrogen peroxide (H2 O2 ). Here, we use the T252E-CYP199A4 variant to study peroxide-driven oxidation activity by using H2 O2 and urea-hydrogen peroxide (UHP). We demonstrate that the T252E variant has a higher stability to H2 O2 in the presence of substrate that can undergo carbon-hydrogen abstraction. This peroxygenase variant could efficiently catalyse O-demethylation and an enantioselective epoxidation reaction (94 % ee). Neither the monooxygenase nor peroxygenase pathways of the P450 demonstrated a significant kinetic isotope effect (KIE) for the oxidation of deuterated substrates. These new peroxygenase variants offer the possibility of simpler cytochrome P450 systems for selective oxidations. To demonstrate this, a light driven H2 O2 generating system was used to support efficient product formation with this peroxygenase enzyme.