Enantioselective inhibition of human CYP2C19 by the chiral pesticide ethofumesate: Prediction of pesticide-drug interactions in humans.

Ethofumesate is a chiral herbicide that may display enantioselective behavior in humans. For this reason, the enantioselective potential of ethofumesate and its main metabolite ethofumesate-2-hydroxy to cause pesticide-drug interactions on cytochrome P450 forms (CYPs) has been evaluated by using human liver microsomes. Among the evaluated CYPs, CYP2C19 had its activity decreased by the ethofumesate racemic mixture (rac-ETO), (+)-ethofumesate ((+)-ETO), and (-)-ethofumesate ((-)-ETO). CYP2C19 inhibition was not time-dependent, but a strong inhibition potential was observed for rac-ETO (IC50 = 5 ± 1 µmol L-1), (+)-ETO (IC50 = 1.6 ± 0.4 µmol L-1), and (-)-ETO (IC50 = 1.8 ± 0.4 µmol L-1). The reversible inhibition mechanism was competitive, and the inhibition constant (Ki) values for rac-ETO (2.6 ± 0.4 µmol L-1), (+)-ETO (1.5 ± 0.2 µmol L-1), and (-)-ETO (0.7 ± 0.1 µmol L-1) were comparable to the Ki values of strong CYP2C19 inhibitors. Inhibition of CYP2C19 by ethofumesate was enantioselective, being almost twice higher for (-)-ETO than for (+)-ETO, which indicates that this enantiomer may be a more potent inhibitor of this CYP form. For an in vitro-in vivo correlation, the Food and Drug Administration's (FDA) guideline on the assessment of drug-drug interactions used in the early stages of drug development was used. The FDA's R1 values were estimated on the basis of the obtained ethofumesate Ki and distribution volume, metabolism, unbound plasma fraction, gastrointestinal and dermal absorption data available in the literature. The correlation revealed that ethofumesate probably inhibits CYP2C19 in vivo for both chronic (oral) and occupational (dermal) exposure scenarios.

Drug-drug interaction of microdose and regular-dose omeprazole with a CYP2C19 inhibitor and inducer.

PURPOSE: A microdose drug-drug interaction (DDI) study may be a valuable tool for anticipating drug interaction at therapeutic doses. This study aimed to compare the magnitude of DDIs at microdoses and regular doses to explore the applicability of a microdose DDI study. PATIENTS AND METHODS: Six healthy male volunteer subjects were enrolled into each DDI study of omeprazole (victim) and known perpetrators: fluconazole (inhibitor) and rifampin (inducer). For both studies, the microdose (100 µg, cold compound) and the regular dose (20 mg) of omeprazole were given at days 0 and 1, respectively. On days 2-9, the inhibitor or inducer was given daily, and the microdose and regular dose of omeprazole were repeated at days 8 and 9, respectively. Full omeprazole pharmacokinetic samplings were performed at days 0, 1, 8, and 9 of both studies for noncompartmental analysis. RESULTS: The magnitude of the DDI, the geometric mean ratios (with perpetrator/omeprazole only) of maximum concentration (Cmax) and area under the curve to the last measurement (AUCt) of the microdose and the regular dose were compared. The geometric mean ratios in the inhibition study were: 2.17 (micro) and 2.68 (regular) for Cmax, and 4.07 (micro), 4.33 (regular) for AUCt. For the induction study, they were 0.26 (micro) and 0.21 (regular) for Cmax, and 0.16 (micro) and 0.15 (regular) for AUCt. There were no significant statistical differences in the magnitudes of DDIs between microdose and regular-dose conditions, regardless of induction or inhibition. CONCLUSION: Our results may be used as partial evidence that microdose DDI studies may replace regular-dose studies, or at least be used for DDI-screening purposes.

In vitro metabolism of bencycloquidium bromide and its inhibitory effects on human P450 isoenzymes: implication of CYP2D6, CYP2C19 and CYP3A4/5.

Bencycloquidium bromide (BCQB) is a novel selective muscarinic M1/M3 receptor antagonist with potent therapeutic effects on rhinitis and chronic obstructive pulmonary disease. The metabolism of BCQB has been investigated in human liver microsomes and human recombinant P450 to elucidate the P450 isozymes responsible for its metabolism in human. Also, the metabolism pathway and the potency of BCQB in inhibiting CYP's various isozymes in humans were investigated. The main biotransformation route of BCQB was NADPH-dependent oxidation. BCQB was metabolized oxidatively to four metabolites that were identified as monohydroxylated derivatives of BCQB at the phenyl and pentyl moieties of the molecule. The results from in vitro inhibition studies indicated that quinidine inhibited 86 % of metabolism of BCQB, while ticlopidine and ketoconazole inhibited 39 and 29 %, respectively. Inhibition studies with selective chemical inhibitors and incubations with human recombinant P450 isoforms demonstrated that the oxidative metabolism of BCQB is mediated by CYP2D6, CYP2C19 and CYP3A4/5, whereas BCQB had no inhibitory effect on any other P450 isoenzyme in humans.

Time-Dependent Inhibition of CYP2C19 by Isoquinoline Alkaloids: In Vitro and In Silico Analysis.

The cytochrome P450 2C19 (CYP2C19) enzyme plays an important role in the metabolism of many commonly used drugs. Relatively little is known about CYP2C19 inhibitors, including compounds of natural origin, which could inhibit CYP2C19, potentially causing clinically relevant metabolism-based drug interactions. We evaluated a series (N = 49) of structurally related plant isoquinoline alkaloids for their abilities to interact with CYP2C19 enzyme using in vitro and in silico methods. We examined several common active alkaloids found in herbal products such as apomorphine, berberine, noscapine, and papaverine, as well as the previously identified mechanism-based inactivators bulbocapnine, canadine, and protopine. The IC50 values of the alkaloids ranged from 0.11 to 210 µM, and 42 of the alkaloids were confirmed to be time-dependent inhibitors of CYP2C19. Molecular docking and three-dimensional quantitative structure-activity relationship analysis revealed key interactions of the potent inhibitors with the enzyme active site. We constructed a comparative molecular field analysis model that was able to predict the inhibitory potency of a series of independent test molecules. This study revealed that many of these isoquinoline alkaloids do have the potential to cause clinically relevant drug interactions. These results highlight the need for studying more profoundly the potential interactions between drugs and herbal products. When further refined, in silico methods can be useful in the high-throughput prediction of P450 inhibitory potential of pharmaceutical compounds.

Effects of tanshinones from Salvia miltiorrhiza on CYP2C19 activity in human liver microsomes: enzyme kinetic and molecular docking studies.

OBJECTIVES: This study aimed to investigate the effects of five tanshinones, the lipophilic components from Danshen (Salvia miltiorrhiza), on CYP2C19 activity in pooled human liver microsomes (HLMs). METHODS: The effects of tanshinones on CYP2C19 activity were compared by enzyme inhibition study using omeprazole 5-hydroxylation in pooled HLMs. The inhibition constant (Ki) values and inhibition modes of effective tanshinones were evaluated by enzyme kinetic study. Molecular docking analysis was used to simulate the binding conformations of tanshinones to the active cavity of human CYP2C19. RESULTS: Dihydrotanshinone and miltirone showed potent inhibitory effects on CYP2C19 activity in a concentration-dependent manner. Tanshinone I showed weaker inhibitory effect, whereas tanshinone IIA and cryptotanshinone had no inhibitory effect. Further enzyme kinetic study showed that the inhibition by dihydrotanshinone and miltirone was a mixed type. The effects of tanshinones were also confirmed by a molecular docking study. Besides, the ethanol extract of Danshen also showed a mixed type of inhibition, whereas the water extract had no inhibitory effect. CONCLUSIONS: The current findings demonstrate the inhibition of CYP2C19 activity by the ethanol extract of Danshen and its components tanshinones, implicating the potential herb-drug interactions between Danshen and therapeutic agents metabolized by CYP2C19 in clinical practice.