Evaluation of 89 compounds for identification of substrates for cynomolgus monkey CYP2C76, a new bupropion/nifedipine oxidase.

Cynomolgus monkeys are widely used in preclinical studies during drug development because of their evolutionary closeness to humans, including their cytochrome P450s (P450s). Most cynomolgus monkey P450s are almost identical (≥90%) to human P450s; however, CYP2C76 has low sequence identity (approximately 80%) to any human CYP2Cs. Although CYP2C76 has no ortholog in humans and is partly responsible for species differences in drug metabolism between cynomolgus monkeys and humans, a broad evaluation of potential substrates for CYP2C76 has not yet been conducted. In this study, a screening of 89 marketed compounds, including human CYP2C and non-CYP2C substrates or inhibitors, was conducted to find potential CYP2C76 substrates. Among the compounds screened, 19 chemicals were identified as substrates for CYP2C76, including substrates for human CYP1A2 (7-ethoxyresorufin), CYP2B6 (bupropion), CYP2D6 (dextromethorphan), and CYP3A4/5 (dextromethorphan and nifedipine), and inhibitors for CYP2B6 (sertraline, clopidogrel, and ticlopidine), CYP2C8 (quercetin), CYP2C19 (ticlopidine and nootkatone), and CYP3A4/5 (troleandomycin). CYP2C76 metabolized a wide variety of the compounds with diverse structures. Among them, bupropion and nifedipine showed high selectivity to CYP2C76. As for nifedipine, CYP2C76 formed methylhydroxylated nifedipine, which was not produced by monkey CYP2C9, CYP2C19, or CYP3A4, as identified by mass spectrometry and estimated by a molecular docking simulation. This unique oxidative metabolite formation of nifedipine could be one of the selective marker reactions of CYP2C76 among the major CYP2Cs and CYP3As tested. These results suggest that monkey CYP2C76 contributes to bupropion hydroxylation and formation of different nifedipine oxidative metabolites as a result of its relatively large substrate cavity.

Effect of lipopolysaccharide on the xenobiotic-induced expression and activity of hepatic cytochrome P450 in mice.

Infection-associated inflammation can alter the expression levels and functions of cytochrome P450s (CYPs). Cyp gene expression is regulated by the activation of several nuclear receptors, including pregnane X receptor (PXR), constitutive androstane receptor (CAR), and aryl hydrocarbon receptor (AhR). These receptors can be activated by xenobiotics, including medicines. Here, to study the xenobiotic-induced fluctuations in CYP during inflammation, we examined the effect of lipopolysaccharide (LPS) treatment on the level of mRNAs encoding hepatic CYPs induced by xenobiotic-activated nuclear receptors, in mice. Both the mRNA induction of Cyp genes and the metabolic activities of CYP proteins were examined. LPS treatment caused a significant decrease in the induced expression of the mRNAs for Cyp3a11, 2c29, 2c55, and 1a2, but not for Cyp2b10. To assess the CYP enzymatic activities, CYP3A-mediated testosterone 6ß-hydroxylation and the intrinsic clearance (CL(int)) of nifedipine in liver microsomes were measured in mice treated with the xenobiotic pregnenolone-16alpha-carbonitrile (PCN) with or without LPS administration. Both assays revealed that the CYP3A activity, which was induced by PCN, declined significantly after LPS treatment, and this decline correlated with the Cyp3a11 mRNA level. In addition, we found that the mRNAs for interleukin (IL)-1ß and tumor necrosis factor (TNF) α were increased after treatment with LPS plus xenobiotics. Our findings demonstrated that LPS treatment reduces the PXR- and AhR-mediated, and possibly CAR-mediated Cyp gene expression and further suggest that these decreases are dependent on inflammatory cytokines in the liver.

Transporter-mediated influx and efflux mechanisms of pitavastatin, a new inhibitor of HMG-CoA reductase.

The purpose of this study was to gain a better understanding of the transport mechanism of pitavastatin, a novel synthetic HMG-CoA reductase inhibitor. Experiments were performed using oocytes of Xenopus laevis expressing several solute carrier (SLC) transporters and recombinant membrane vesicles expressing several human ABC transporters. The acid form of pitavastatin was shown to be a substrate for human OATP1, OATP2, OATP8, OAT3 and NTCP, and for rat Oatp1 and Oatp4 with relatively low K(m) values. In contrast, these SLC transporters were not involved in the uptake of the lactone form. A significant stimulatory effect was exhibited by pitavastatin lactone, while the acid form did not exhibit ATPase hydrolysis of P-glycoprotein. In the case of breast cancer resistant protein (BCRP), the acid form of pitavastatin is a substrate, whereas the lactone form is not. Taking these results into consideration, several SLC and ABC transporters were identified as critical to the distribution and excretion of pitavastatin in the body. This study showed, for the first time, that acid and lactone forms of pitavastatin differ in substrate activity towards uptake and efflux transporters. These results will potentially contribute to the differences in the pharmacokinetic profiles of pitavastatin.

Metabolic stability and uptake by human hepatocytes of pitavastatin, a new inhibitor of HMG-CoA reductase.

To gain a better understanding of the metabolic stability and transport of pitavastatin (CAS 147526-32-7), a new and potent 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor, experiments were conducted using human hepatocytes and oocytes of Xenopus laevis expressing human organic anion transporting polypeptide-2 (OATP2), respectively. Almost the entire radioactivity was from the unchanged substance or lactone form in human hepatocytes, and the cytochrome P450 (CYP)-mediated metabolism of pitavastatin was negligible. The results suggested that CYPs are not critically involved in determining the metabolic fate of pitavastatin. The hepatic uptake of pitavastatin reached saturation with a Km of 2.99 +/- 0.79 micromol/L. Also, the uptake of pitavastatin was mediated by OATP2 expressed in oocytes with a Km of 5.53 +/- 1.70 micromol/L. These results indicated that OATP2 plays a major role in the distribution of pitavastatin in liver. Furthermore, to elucidate the increase in the plasma concentration of pitavastatin in a clinical setting, the inhibitory effect of ciclosporin (cyclosporin A, CAS 59865-13-3) on the uptake of pitavastatin was examined. The uptake of pitavastatin was inhibited in the presence of cyclosporin A and the apparent IC50 value was 2.91 +/- 0.78 micromol/L. This result may at least partly explain the drug-drug interaction between pitavastatin and cyclosporin A. In conclusion, the characterization of transporters needs to be taken into account to avoid transporter-mediated drug-drug interaction.