Role of the OATP Transporter Family and a Benzbromarone-SensitiveEfflux Transporter in the Hepatocellular Disposition of Vincristine.

PURPOSE: Vincristine is known to interfere with OATP-mediated uptake of other compounds, hinting that vincristine itself could be a substrate of OATP transporters. The present study therefore aimed to investigate the role of OATP transporters in the hepatocellular disposition of vincristine. METHODS: Vincristine uptake was studied in suspended rat and human hepatocytes as well as OATP-transfected Chinese hamster ovary (CHO) cells in the absence and presence of OATP transporter inhibitors. Membrane vesicles containing MDR1 or MRP1/2/3 were used to directly assess the role of these efflux transporters in vincristine disposition. RESULTS: Uptake in suspended rat hepatocytes was temperature-dependent and could be inhibited by a range of OATP inhibitors. Furthermore, the MRP-inhibitor benzbromarone, but none of the tested MDR1 inhibitors, reduced vincristine efflux in rat and human suspended hepatocytes. OATP1B1-, OATP1B3- and OATP2B1- transfected CHO cells showed significantly increased vincristine uptake as compared to wild-type cells. Moreover, uptake in OATP-transfected CHO cells was reduced by OATP inhibitors. However, uptake studies in suspended human hepatocytes showed that only 10% of the total vincristine uptake process could be attributed to OATP-mediated transport. Studies with transporter-expressing membrane vesicles confirmed vincristine as an MDR1 substrate, while MRP1/2/3-mediated transport of vincristine could not be observed with this model system. CONCLUSIONS: Our findings show the involvement of OATP transporters in the disposition of vincristine in rat and human hepatocytes. However, in both species, hepatic uptake is overshadowed by a benzbromarone-sensitive efflux mechanism, possibly MRP3.

Transport-Metabolism Interplay of Atazanavir in Rat Hepatocytes.

The aim of this study was to explore the mechanisms governing the intra- to extracellular unbound concentration ratio (Kpu,u) for the HIV protease inhibitor atazanavir (ATV) in rat hepatocytes. We had previously proposed a new method to determine Kpu,u by using the unbound Km values from metabolism studies with suspended rat hepatocytes and rat liver microsomes. Following that method, we determined that the value of ATV Kpu,u was 0.32, indicating that ATV hepatocellular clearance is uptake rate-limited. This hypothesis was supported by the linear correlation between Kpu,u and active uptake clearance (P = 0.04; R(2)=0.82) in the presence of increasing concentrations of the uptake transport inhibitor losartan. Moreover, in contrast to an expected increase of Kpu,u upon inhibition of ATV metabolism, a decrease of Kpu,u was observed, suggesting an increased impact of sinusoidal efflux. In summary, involvement of active uptake transport does not guarantee high intracellular accumulation; however, it has a key role in regulating intracellular drug concentrations and drug metabolism. These findings will help improve future in vitro-to-in vivo extrapolations and likewise physiologically based pharmacokinetic models.