Potent inhibition of CYP1A2 by Frutinone A, an active ingredient of the broad spectrum antimicrobial herbal extract from P. fruticosa.

1. Frutinone is an active ingredient extracted from the lipophilic fraction of the Polygala Fruticosa demonstrating various antibacterial and fungal properties. The aim of this study was to characterize its metabolism in an effort to understand metabolism based drug-herb interactions. 2. In vitro metabolic clearance and metabolite identification studies were done using cryopreserved hepatocytes. Reaction phenotyping and inhibition studies were done using human liver microsomes and recombinant cytochrome P450s (CYPs). Frutinone A-CYP1A2 interactions were rationalized using docking simulations. 3. Hepatic clearance was predicted to be low (7.17 mL/min/kg), with reaction phenotyping studies indicating no clearance by the enzymes tested. Frutinone was identified as a potent inhibitor of CYP1A2 with moderate effects on CYP2C19, 2C9, 2D6 and 3A4. CYP1A2 inhibition was reversible and characterised by an IC(50) of 0.56 µM. Inhibition was differential showing mixed (K(i) = 0.48 µM) and competitive (K(i) = 0.31 µM) inhibition with 3-cyano-7-ethoxycoumarin and ethoxyresorufin, respectively. Two binding sites, one for inhibitors and the other for substrates were identified in silico. 4. The potent CYP1A2 inhibition by Frutinone A could be predictive of the potential drug-herb interaction risk in the use of herbal extracts from P. fruticosa. The data suggest future pharmacological research on this chromocoumarin should take metabolic properties into account.

In vitro and in silico identification and characterization of thiabendazole as a mechanism-based inhibitor of CYP1A2 and simulation of possible pharmacokinetic drug-drug interactions.

Thiabendazole (TBZ) and its major metabolite 5-hydroxythiabendazole (5OH-TBZ) were screened for potential time-dependent inhibition (TDI) against CYP1A2. Screen assays were carried out in the absence and presence of NADPH. TDI was observed with both compounds, with k(inact) and K(I) values of 0.08 and 0.02 min(-1) and 1.4 and 63.3 microM for TBZ and 5OH-TBZ, respectively. Enzyme inactivation was time-, concentration-, and NADPH-dependent. Inactivation by TBZ was irreversible by dialysis and oxidation by potassium ferricyanide, and there was no protection by glutathione. 5OH-TBZ was a weak TDI of CYP1A2, and enzyme activity was recovered by dialysis. IC(50) determination of TBZ and 5OH-TBZ showed both compounds to be potent inhibitors, with IC(50) values of 0.83 and 13.05 microM, respectively. IC(50) shift studies also demonstrated that TBZ was a TDI of CYP1A2. In silico methods identified the thiazole group as a TDI fragment and predicted it as the site of metabolism. The observation pointed to epoxidation of the thiazole and the benzyl rings of TBZ as possible routes of metabolism and mechanisms of TDI. Drug-drug interaction (DDI) simulation studies using SimCyp showed good predictions for competitive inhibition. However, predictions for mechanism-based inhibition (MBI)-based DDI were not in agreement with clinical observations. There was no TBZ accumulation upon chronic administration of the drug. The in vitro MBI findings might therefore not be capturing the in vivo situation in which the proposed bioactivation route is minor. This might be the case for TBZ in which, in vivo, UDP glucuronosyltransferases and sulfanotransferase metabolize and eliminate the 5OH-TBZ.