Study of effect of rifampin and tanshinone II A on pravastatin transport via BSEP in sandwich-cultured rat hepatocytes / 中国药理学通报

Aim To elucidate the effect of rifampin and tanshinone II A on BSEP transport capacity using pravastatin as the BSEP substrate in sandwich-cultured rat hepatocytes (SCRH). Methods SCRH model was established. The doses of drugs were determined by MIT. A HPLC-MS/MS method was developed and was conducted method validation to detect the concentration of pravastatin. The effect of rifampin and tanshinone D A on the concentration of pravastatin in the bile duct was investigated. And the biliary excretion index ( BEI) was calculated. Results The SCRH model was successfully developed. The appropriate doses of rifampin, tanshinone DA, glibenclamide and pravastatin were determined. A stable and reliable HPLC-MS/MS method for the determination of pravastatin was established Compared with blank control group, rifampin reduced the concentration of pravastatin in the bile duct and the BEI of pravastatin. The high concentration of rifampin caused the steepest downward trends ( P < 0 . 0 1 ) . Compared with high concentration group of rifampin, the concentration of pravastatin in the bile duct and the BEI of pravastatin gradually increased after the combination of rifampin and tanshinone II A, and the effect of high concentration of tanshinone II A was the most significant ( P < 0. 0 1 ) . Conclusions Rifampin could inhibit the function of BSEP in SCRH. The combination of tanshinone D A and rifampin could reverse the inhibitor)' effect of BSEP transport capacity caused by rifampin.

Alpha-naphthylisothiocyanate modulates hepatobiliary transporters in sandwich-cultured rat hepatocytes.

Alpha-naphthylisothiocyanate (ANIT) induces intra-hepatic cholestasis mixed with hepatocellular injury mainly by bile ductular damage. However, its direct effect on hepatic parenchymal cells (hepatocytes) is unclear. Sandwich-cultured rat hepatocytes (SCRH) were applied to clarify this question. Though cytotoxicity was not observed (0-180 µM) in ANIT-treated SCRH, metabonomics analysis of the hepatocytes revealed a shift in the metabolic pattern and a decrease in cellular cholesterol level, accompanied by an increase in total bile acids after 48 h ANIT (5-45 µM) treatment. To assess the function of major hepatic bile acid transporters, the accumulation and efflux of [D-Pen(2,5)]-enkephalin (DPDPE), 5 (and 6)-carboxy-2',7'-dichlorofluorescein (CDF) diacetate promoiety and deuterium-labeled sodium taurocholate (d8-TCA) were measured. ANIT incubation for either 30 min or 48 h led to dose-dependent decreases in the biliary excretion index (BEI) of DPDPE and CDF, as well as the intracellular accumulation of d8-TCA, CDF and DPDPE. The basolateral efflux of d8-TCA was also decreased with its BEI barely changed. mRNA expression of multiple uptake transporters and bile acid synthesizing enzymes was down-regulated after 48 h incubation. In conclusion, ANIT could directly induce retention of bile acids in hepatocytes by inhibiting the function of bile acid transporters, which might contribute to its cholestatic effect.

Hepatocyte-based in vitro model for assessment of drug-induced cholestasis.

Early detection of drug-induced cholestasis remains a challenge during drug development. We have developed and validated a biorelevant sandwich-cultured hepatocytes- (SCH) based model that can identify compounds causing cholestasis by altering bile acid disposition. Human and rat SCH were exposed (24-48h) to known cholestatic and/or hepatotoxic compounds, in the presence or in the absence of a concentrated mixture of bile acids (BAs). Urea assay was used to assess (compromised) hepatocyte functionality at the end of the incubations. The cholestatic potential of the compounds was expressed by calculating a drug-induced cholestasis index (DICI), reflecting the relative residual urea formation by hepatocytes co-incubated with BAs and test compound as compared to hepatocytes treated with test compound alone. Compounds with clinical reports of cholestasis, including cyclosporin A, troglitazone, chlorpromazine, bosentan, ticlopidine, ritonavir, and midecamycin showed enhanced toxicity in the presence of BAs (DICI≤0.8) for at least one of the tested concentrations. In contrast, the in vitro toxicity of compounds causing hepatotoxicity by other mechanisms (including diclofenac, valproic acid, amiodarone and acetaminophen), remained unchanged in the presence of BAs. A safety margin (SM) for drug-induced cholestasis was calculated as the ratio of lowest in vitro concentration for which was DICI≤0.8, to the reported mean peak therapeutic plasma concentration. SM values obtained in human SCH correlated well with reported % incidence of clinical drug-induced cholestasis, while no correlation was observed in rat SCH. This in vitro model enables early identification of drug candidates causing cholestasis by disturbed BA handling.

Toxicity and intracellular accumulation of bile acids in sandwich-cultured rat hepatocytes: role of glycine conjugates.

Excessive intrahepatic accumulation of bile acids (BAs) is a key mechanism underlying cholestasis. The aim of this study was to quantitatively explore the relationship between cytotoxicity of BAs and their intracellular accumulation in sandwich-cultured rat hepatocytes (SCRH). Following exposure of SCRH (on day-1 after seeding) to various BAs for 24h, glycine-conjugated BAs were most potent in exerting toxicity. Moreover, unconjugated BAs showed significantly higher toxicity in day-1 compared to day-3 SCRH. When day-1/-3 SCRH were exposed (0.5-4h) to 5-100µM (C)DCA, intracellular levels of unconjugated (C)DCA were similar, while intracellular levels of glycine conjugates were up to 4-fold lower in day-3 compared to day-1 SCRH. Sinusoidal efflux was by far the predominant efflux pathway of conjugated BAs both in day-1 and day-3 SCRH, while canalicular BA efflux showed substantial interbatch variability. After 4h exposure to (C)DCA, intracellular glycine conjugate levels were at least 10-fold higher than taurine conjugate levels. Taken together, reduced BA conjugate formation in day-3 SCRH results in lower intracellular glycine conjugate concentrations, explaining decreased toxicity of (C)DCA in day-3 versus day-1 SCRH. Our data provide for the first time a direct link between BA toxicity and glycine conjugate exposure in SCRH.