Probe drug T-1032 N-oxygenation mediated by cytochrome P450 3A5 in human hepatocytes in vitro and in humanized-liver mice in vivo.

Polymorphic cytochrome P450 3A5 (CYP3A5) expression contributes to individual differences in the pharmacokinetics of probe drugs. The identification of suitable in vivo CYP3A5 probes would benefit drug metabolism and drug interaction studies using chimeric mice with humanized liver. In this study, we investigated the pharmacokinetic profiles of T-1032, which is known as an in vitro CYP3A5 probe substrate, using humanized-liver mice. Substantial N-oxygenation of T-1032 was observed in hepatocytes from humans and from humanized-liver mice. Hepatocytes from the human donor genotyped as CYP3A5∗3/∗3 (poor expressers) showed significantly lower T-1032 N-oxidation rates than those from donors harboring CYP3A5∗1. After a single oral dose of T-1032 (1.0 mg/kg) in humanized-liver mice, the plasma levels of T-1032 N-oxide were higher in five mice with CYP3A5∗1/∗7 hepatocytes than in four mice with CYP3A5∗3/∗3 hepatocytes. The maximum concentrations of T-1032 N-oxide after oral administration of T-1032 in humanized-liver mice with CYP3A5∗1/∗7 hepatocytes were twice (a significant difference) those from humanized-liver mice with CYP3A5∗3/∗3 hepatocytes. These results suggest that polymorphic CYP3A5-dependent T-1032 N-oxidation was observed in humanized liver mice in vitro and in vivo. However, the contribution of CYP3A5 genotypes may have little or only limited effects on the overall pharmacokinetic profiles of T-1032 in vivo.

Clinical determinants of calcineurin inhibitor disposition: a mechanistic review.

The calcineurin inhibitors (CNIs) tacrolimus and cyclosporine are widely used immunosuppressive drugs characterized by high pharmacokinetic and pharmacodynamic variability, both between and within patients. CNIs are highly lipophilic, poorly soluble, undergo extensive first-pass metabolism and are cleared by the liver. In both gut and liver, CNIs are substrates for the cytochrome P450 (CYP) enzymes 3A4 and 3A5 as well as the P-glycoprotein (P-gp) transporter, whose functions are determined by a complex interplay between genetic polymorphisms, the inductive or inhibitory effects of many drugs, herbs, food constituents and endogenous substances such as uremic toxins in case of end-stage renal disease. The current literature is reviewed for all common clinical determinants of variability in CNI disposition such as food intake, diarrhea and other intestinal pathology, anemia, hypoalbuminemia, hyperlipidemia, liver and kidney disease, aging, ethnicity, formulation and time post-transplant, focusing on the underlying mechanisms. Drugs and herb- and food constituents mainly interact with CNIs at the gut level by affecting bioavailability, with interactions generally being much more pronounced in case of oral compared with intravenous co-administration. Cyclosporine disposition is less susceptible to these interactions compared with tacrolimus, possibly because cyclosporine is itself a moderately strong CYP3A4- and strong P-gp inhibitor, blunting the effect of additional inhibitors. P-gp also has a major role in limiting distribution of CNI to tissues such as the brain, placenta, lymphocytes and kidney. Inactivating polymorphisms and inhibition of P-gp have the potential to significantly increase CNI exposure in these tissues with possible implications for toxicity and efficacy.

Progressive decline in tacrolimus clearance after renal transplantation is partially explained by decreasing CYP3A4 activity and increasing haematocrit.

AIMS: The long-term disposition of tacrolimus following kidney transplantation is characterized by a gradual decrease in dose requirements and increase in dose-corrected exposure. This phenomenon has been attributed to a progressive decline in cytochrome P450 3A4 (CYP3A4) activity, although this has never been demonstrated in vivo. METHODS: Sixty-five tacrolimus- and 10 cyclosporine-treated renal transplant recipients underwent pharmacokinetic testing at day 7 and months 1, 3, 6 and 12 after transplantation, including 8-h area under the concentration-time curve (AUC) for tacrolimus or cyclosporine and assessment of CYP3A4 activity using oral and intravenous midazolam (MDZ) drug probes. RESULTS: Tacrolimus clearance decreased gradually throughout the entire first year but only in CYP3A5*3/*3 homozygous recipients (25.6 ± 11.1 l h(-1) at day 7; 17 ± 9.1 l h(-1) at month 12; P < 0.001). In mixed model analysis, decreasing CYP3A4 activity, measured by apparent oral MDZ clearance (924 ± 443 ml min(-1) at day 7 vs. 730 ± 344 ml min(-1) at month 1; P < 0.001), explained 55.4% of the decline in tacrolimus clearance in the first month. CYP3A4 activity decreased by 18.9 ml min(-1) for every milligram of methylprednisolone dose tapering within the first month; beyond this point it remained stable. A gradual rise in haematocrit throughout the entire first year explained 31.7% of the decrease in tacrolimus clearance in the first month and 23.6% of the decrease between months 1 and 12. Cyclosporine clearance did not change over time. CONCLUSIONS: The maturation of tacrolimus disposition in the first year after renal transplantation observed in CYP3A5*3/*3 homozygous patients can partly be explained by a (steroid tapering-related) decline in CYP3A4 activity and a progressive increase in haematocrit.