The constitutive androstane receptor (CAR; NR1I3) is a key transcriptional factor that regulates genes encoding drug-metabolizing enzymes and drug transporters. However, studies on regulation of CAR target genes via up- or down-regulation of CAR are limited. In this study, we examined the effects of PPARalpha agonists (ciprofibrate, bezafibrate, fenofibrate and WY14643) on the expression of CAR and its target gene CYP2B1/2 in rat primary hepatocytes. Results from real-time PCR analysis showed that CAR and CYP2B1/2 mRNAs exhibit increases in response to all PPARalpha agonists studied (5 to 10-folds of control). Pretreatment of cells with cycloheximide, an inhibitor of protein synthesis, completely suppressed increase in CYP2B1/2 mRNA in response to ciprofibrate, suggesting that protein synthesis is required in this process. In addition, the induction of CAR by ciprofibrate on the protein level was observed with nuclear extracts as well as total cell lysates. These results indicate that CYP2B1/2 mRNAs are induced by PPARalpha agonists and that this effect is accompanied by increase in the expression of CAR gene at both mRNA and nuclear protein levels. Activated PPARalpha may increase functional CAR protein, which can induce the expression of CAR target genes such as CYP2B.
ONO-2160 is a newly developed oral estertype prodrug of levodopa for removing the problems in use of levodopa. It has a structure in which two of the same substituents are bound to levodopa. It is important to understand the pharmacokinetics and metabolic pathway for new drug candidate compounds. The aim of this study was to identify the major enzymes that contribute to the metabolism of ONO-2160 in human plasma. ONO-2160 was hydrolyzed by human serum albumin (HSA) and α 1 -acid glycoprotein (AGP) in human plasma, although the hydrolysis was not inhibited by various reported esterase inhibitors. The value of the intrinsic clearance per milliliter of plasma of ONO-2160 in AGP solution was greater than that in HSA solution and was comparable to that in human plasma. Therefore, AGP is responsible for the hydrolysis of ONO-2160 in human plasma. ONO-M, which is an intermediate metabolite of ONO-2160, has a structure in which one substituent is removed from ONO-2160 and was mainly generated in AGP solution, but not in human plasma or HSA solution. The hydrolysis of ONO-M by HSA was much greater than by AGP. These results indicate that ONO-M, which is mainly generated from ONO-2160 by AGP, is rapidly hydrolyzed by HSA, and that ONO-2160 generates levodopa via ONO-M in a relay-type reaction through AGP and HSA in human plasma. It has not been reported that AGP has esteraselike activity. These findings could be useful information for drug development of the ester-type prodrug. KEYWORDS: ester-type prodrug, carboxyl esterase (CES), human serum albumin (HSA), α 1 -acid glycoprotein (AGP), in vitro−in vivo extrapolation (IVIVE)
The cause of nonlinear pharmacokinetics (PK) (more than dose-proportional increase in exposure) of a urea derivative under development (compound A: anionic compound [pKa: 4.4]; LogP: 6.5; and plasma protein binding: 99.95%) observed in a clinical trial was investigated. Compound A was metabolized by CYP3A4, UGT1A1, and UGT1A3 with unbound K of 3.3-17.8 μmol/L. OATP1B3-mediated uptake of compound A determined in the presence of human serum albumin (HSA) showed that unbound K and V decreased with increased HSA concentration. A greater decrease in unbound K than in V resulted in increased uptake clearance (V/unbound K) with increased HSA concentration, the so-called albumin-mediated uptake. At 2% HSA concentration, unbound K was 0.00657 μmol/L. A physiologically based PK model assuming saturable hepatic uptake nearly replicated clinical PK of compound A. Unbound K for hepatic uptake estimated from the model was 0.000767 μmol/L, lower than the in vitro unbound K at 2% HSA concentration, whereas decreased K with increased concentration of HSA in vitro indicated lower K at physiological HSA concentration (4%-5%). In addition, unbound K values for metabolizing enzymes were much higher than unbound K for OATP1B3, indicating that the nonlinear PK of compound A is primarily attributed to saturated OATP1B3-mediated hepatic uptake of compound A.
Functional interplay between transporters and drug-metabolizing enzymes is currently one of the hottest topics in the field of drug metabolism and pharmacokinetics. Uptake transporter-enzyme interplay is important to determine intrinsic hepatic clearance based on the extended clearance concept. Enzyme and efflux transporter interplay, which includes both sinusoidal (basolateral) and canalicular efflux transporters, determines the fate of metabolites formed in the liver. As sandwich-cultured hepatocytes (SCHs) maintain metabolic activities and form a canalicular network, the whole interplay between uptake and efflux transporters and drug-metabolizing enzymes can be investigated simultaneously. In this article, we review the utility and applicability of SCHs for mechanistic understanding of hepatic disposition of both parent drugs and metabolites. In addition, the utility of SCHs for mimicking species-specific disposition of parent drugs and metabolites in vivo is described. We also review application of SCHs for clinically relevant prediction of drug-drug interactions caused by drugs and metabolites. The usefulness of mathematical modeling of hepatic disposition of parent drugs and metabolites in SCHs is described to allow a quantitative understanding of an event in vitro and to develop a more advanced model to predict in vivo disposition.
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