Key mutations alter the cytochrome P450 BM3 conformational landscape and remove inherent substrate bias.

Cytochrome P450 monooxygenases (P450s) have enormous potential in the production of oxychemicals, due to their unparalleled regio- and stereoselectivity. The Bacillus megaterium P450 BM3 enzyme is a key model system, with several mutants (many distant from the active site) reported to alter substrate selectivity. It has the highest reported monooxygenase activity of the P450 enzymes, and this catalytic efficiency has inspired protein engineering to enable its exploitation for biotechnologically relevant oxidations with structurally diverse substrates. However, a structural rationale is lacking to explain how these mutations have such effects in the absence of direct change to the active site architecture. Here, we provide the first crystal structures of BM3 mutants in complex with a human drug substrate, the proton pump inhibitor omeprazole. Supported by solution data, these structures reveal how mutation alters the conformational landscape and decreases the free energy barrier for transition to the substrate-bound state. Our data point to the importance of such "gatekeeper" mutations in enabling major changes in substrate recognition. We further demonstrate that these mutants catalyze the same 5-hydroxylation reaction as performed by human CYP2C19, the major human omeprazole-metabolizing P450 enzyme.

What makes a P450 tick?

The cytochromes P450 (P450s) are probably nature's most versatile enzymes in terms of both their vast substrate range and the diverse types of molecular transformations performed across the P450 enzyme superfamily. The P450s exquisitely perform highly specific oxidative chemistry, utilizing a sophisticated catalytic reaction mechanism. Recent studies have provided the first definitive characterization of the transient reaction cycle intermediate (compound I) responsible for the majority of P450 oxidative reactions. This major advance comes at a time when P450 engineering has facilitated the elucidation of several mammalian P450 structures and generated P450 variants with novel substrate specificity and reactivity. This review describes recent advances in P450 research and the ramifications for biotechnological and biomedical exploitation of these enzymes.

Direct detection of membrane channels from gels using water-in-oil droplet bilayers.

We form planar lipid bilayers between an aqueous droplet and a hydrogel support immersed in a lipid-oil solution. By scanning the bilayer over the surface of an SDS-PAGE gel, we are able to directly detect membrane proteins from gels using single-channel recording. Using this technique, we are able to examine low levels of endogenous protein from cell extracts without the need for over-expression. We also use droplet bilayers to detect small molecules from hydrogels. The bilayers show enhanced stability compared to conventional planar lipid bilayers, and both bilayer size and position can be controlled during an experiment. Hydrogel scanning with droplet bilayers provides a new method for the discovery and characterization of ion channels with the potential for high-throughput screening.