Multiresolution molecular dynamics simulations reveal the interplay between conformational variability and functional interactions in membrane-bound cytochrome 2B4

Cytochrome P450 2B4 ( CYP 2B4) is one of the best characterized CYPs and serves as a key model system for understanding the mechanisms of microsomal class II CYPs, which metabolize most known drugs. The highly flexible nature of CYP 2B4 is apparent from crystal structures that show the active site with either a wide open or a closed heme binding cavity. Here, we investigated the conformational ensemble of the full-length CYP 2B4 in a phospholipid bilayer, using multiresolution molecular dynamics (MD) simulations. Coarse-grained MD simulations revealed two predominant orientations of CYP 2B4’s globular domain with respect to the bilayer. Their refinement by atomistic resolution MD showed adaptation of the enzyme’s interaction with the lipid bilayer, leading to open configurations that facilitate ligand access to the heme binding cavity. CAVER analysis of enzyme tunnels, AquaDuct analysis of water routes, and Random Acceleration Molecular Dynamics simulations of ligand dissociation support the conformation-dependent passage of molecules between the active site and the protein surroundings. Furthermore, simulation of the re-entry of the inhibitor bifonazole into the open conformation of CYP 2B4 resulted in binding at a transient hydrophobic pocket within the active site cavity that may play a role in substrate binding or allosteric regulation. Together, these results show how the open conformation of CYP 2B4 facilitates binding of substrates from and release of products to the membrane, whereas the closed conformation prolongs the residence time of substrates or inhibitors and selectively allows the passage of smaller reactants via the solvent and water channels. Impact Our findings from multiresolution molecular dynamics simulations elucidate the structural dynamics of the membrane-bound CYP 2B4 enzyme and how these affect substrate recognition and processing, as well as inhibitor binding. As CYP 2B4 is a representative of the class of cytochrome P450 enzymes that metabolize most known drugs, the insights from this study are pertinent to the prediction of drug metabolism and the design of CYP inhibitors as therapeutics. ### Competing Interest Statement The authors have declared no competing interest.