Membrane-bound cytochrome P4503A4 (CYP3A4) is the major source of enzymatic drug metabolism. Although several structural models of CYP3A4 in various ligand complexes are available, none includes a lipid bilayer. Details of the effects of the membrane on protein dynamics and solvation, and access channels for ligands, remain uncertain. H/D exchange mass spectrometry (H/DXMS) with ligand free CYP3A4 containing a deletion of residues 3-12, compared to that of the full length wild type, in lipid nanodiscs afforded 91% sequence coverage. Deuterium exchange was fast in the F- and G-helices, HI loop, and C-terminal loop. In contrast, there is very low exchange in the F'- and G'-helices. The results are consistent with the overall membrane orientation of CYP3A4 suggested by published MD simulations and spectroscopic results, and the solvent accessibility of the F/G loop suggests that it is not deeply membrane embedded. Addition of ketoconazole results in only modest, but global, changes in solvent accessibility. Interestingly, with ketoconazole bound some peptides become less solvent accessible or dynamic, including the F- and G-helices, but several peptides demonstrate modestly increased accessibility. Differential scanning calorimetry (DSC) of CYP3A4-nanodiscs suggests membrane-induced stabilization compared to that of aggregated CYP3A4 in buffer, and this stabilization is enhanced upon addition of the ligand ketoconazole. This ligand-induced stabilization is accompanied by a very large increase in Delta H for CYP3A4 denaturation in nanodiscs, possibly due to increased CYP3A4-membrane interactions. Together, the results suggest a distinct orientation of CYP3A4 on the lipid membrane, and they highlight likely solvent access channels, which are consistent with several MD simulations.

• 出版日期2016-2-23