Differential expression of basolateral and canalicular organic anion transporters during regeneration of rat liver

BACKGROUND & AIMS: Liver regeneration in response to various forms of injury or surgical resection is a complex process resulting in restoration of the original liver mass and maintenance of liver-specific functions such as bile formation. However, liver regeneration is frequently associated with cholestasis, whose molecular pathogenesis remains unknown. METHODS: To study the molecular mechanisms leading to cholestasis, expression of all major hepatic organic anion transporters contributing to bile formation was determined for up to 2 weeks in rats after 70% partial hepatectomy. RESULTS: Inversely related to serum bile acid levels, basolateral transporters including the sodium-taurocholate cotransporter (Ntcp) and the organic anion transporting polypeptides Oatp1 and Oatp2 were markedly down-regulated at both protein and steady-state mRNA levels by 50%-60% of controls (P > 0.05) during early replicative stages of regeneration (12 hours to 2 days) with a slightly delayed time course for Oatp2. Expression of all basolateral transporters returned to control values between 4 and 4 days after partial hepatectomy. In contrast, protein and mRNA expression of both the canalicular ATP-dependent bile salt export pump (Bsep) and the multiorganic anion transporter Mrp2 remained unchanged or were slightly increased during liver regeneration, but also returned to control values 7-14 days after partial hepatectomy. CONCLUSIONS: The data suggest a differential regulation of basolateral and canalicular organic anion transporters in the regenerating liver. Unaltered expression of Bsep and Mrp2 provides a potential molecular mechanism for regenerating liver cells to maintain or even increase bile secretion expressed per weight of remaining liver. However, down-regulation of basolateral organic anion transporters might protect replicating liver cells by diminishing uptake of potentially hepatotoxic bile salts, because the remaining liver initially cannot cope with the original b