Inhibition of Cytochrome P450 3A4 by a Pyrimidineimidazole:  Evidence for Complex Heme Interactions

PH-302 inhibits the inducible form of nitric oxide synthase (iNOS) by coordinating with the heme of the monomeric form and preventing formation of the active dimer. Inherent with the mechanism of pharmacology for this compound was the inhibition of cytochrome P450 3A4 (P450 3A4), observed from early ADME screening. Further investigation showed that PH-302 inhibited P450 3A4 competitively with a K_i of 2.0 μM against both midazolam and testosterone hydroxylation in human liver microsomes. As expected, spectral binding analysis demonstrated that inhibition was a result of type II coordination to the P450 heme with the imidazole moiety of PH-302, although only 72% of the maximal absorbance difference was achievable with PH-302 compared to that of the smaller ligand imidazole. Time-dependent inhibition of P450 3A4 by PH-302 was also observed because of metabolite-inhibitory (MI) complex formation via metabolism of the methylenedioxyphenyl group. The profile for time-dependent inhibition in recombinant P450 3A4 was biphasic, and was kinetically characterized by a k_inact of 0.08 min^-1 and a K_i of 1.2 μM for the first phase (0−1.5 min) and a k_inact of 0.06 min^-1 and a K_i of 23.8 μM for the second phase (1.5−10 min). Spectral characterization of the PH-302 MI complex demonstrated that formation began to plateau within 3 min, consistent with the kinetic profile of inactivation by PH-302. Meanwhile, spectral evidence for the imidazole-derived type II difference spectrum of PH-302 was captured simultaneously with the formation of the MI complex. The presence of simultaneously operable type II coordination and rapidly saturable MI complex formation with heme by PH-302 indicates the presence of complex heme interactions with this unique molecule. Information from these mechanistic studies adds to our understanding of the nature of P450 3A4 inhibition by PH-302 and provides a potentially useful tool compound for future studies investigating binding interactions in this important drug-metabolizing enzyme.