Frei Pascal, Gao Bo, Hagenbuch Bruno, Mate Alfonso, Biber Jürg, Murer Heini, Meier Peter J, Stieger Bruno
Division of Clinical Pharmacology and Toxicology, Dept. of Medicine, Univ. Hospital Zürich, Rämistrasse 100, CH-8091 Zürich, Switzerland.
Am J Physiol Gastrointest Liver Physiol. 2005 Apr;288(4):G771-8. doi: 10.1152/ajpgi.00272.2004. Epub 2004 Nov 24.
Hepatocytes and cholangiocytes release ATP into bile, where it is rapidly degraded into adenosine and P(i). In rat, biliary P(i) concentration (0.01 mM) is approximately 100-fold and 200-fold lower than in hepatocytes and plasma, respectively, indicating active reabsorption of biliary P(i). We aimed to functionally characterize canalicular P(i) reabsorption in rat liver and to identify the involved P(i) transport system(s). P(i) transport was determined in isolated rat canalicular liver plasma membrane (LPM) vesicles using a rapid membrane filtration technique. Identification of putative P(i) transporters was performed with RT-PCR from liver mRNA. Phosphate transporter protein expression was confirmed by Western blotting in basolateral and canalicular LPM and by immunofluorescence in intact liver. Transport studies in canalicular LPM vesicles demonstrated sodium-dependent P(i) uptake. Initial P(i) uptake rates were saturable with increasing P(i) concentrations, exhibiting an apparent K(m) value of approximately 11 muM. P(i) transport was stimulated by an acidic extravesicular pH and by an intravesicular negative membrane potential. These data are compatible with transport characteristics of sodium-phosphate cotransporters NaPi-IIb, PiT-1, and PiT-2, of which the mRNAs were detected in rat liver. On the protein level, NaPi-IIb was detected at the canalicular membrane of hepatocytes and at the brush-border membrane of cholangiocytes. In contrast, PiT-1 and PiT-2 were detected at the basolateral membrane of hepatocytes. We conclude that NaPi-IIb is most probably involved in the reabsorption of P(i) from primary hepatic bile and thus might play an important role in the regulation of biliary P(i) concentration.
肝细胞和胆管细胞将ATP释放到胆汁中,在胆汁中ATP迅速降解为腺苷和无机磷酸(P(i))。在大鼠中,胆汁中的P(i)浓度(0.01 mM)分别比肝细胞和血浆中的低约100倍和200倍,这表明胆汁中的P(i)被主动重吸收。我们旨在对大鼠肝脏胆小管P(i)重吸收进行功能特性分析,并鉴定所涉及的P(i)转运系统。使用快速膜过滤技术在分离的大鼠胆小管肝细胞膜(LPM)囊泡中测定P(i)转运。通过从肝脏mRNA进行RT-PCR来鉴定假定的P(i)转运蛋白。通过蛋白质免疫印迹法在基底外侧和胆小管LPM中以及通过完整肝脏中的免疫荧光法来确认磷酸盐转运蛋白的表达。在胆小管LPM囊泡中的转运研究表明存在钠依赖性P(i)摄取。随着P(i)浓度增加,初始P(i)摄取速率呈饱和状态,表观K(m)值约为11 μM。酸性细胞外pH值和细胞内负膜电位可刺激P(i)转运。这些数据与钠-磷酸盐共转运蛋白NaPi-IIb、PiT-1和PiT-2的转运特性相符,在大鼠肝脏中检测到了它们的mRNA。在蛋白质水平上,在肝细胞的胆小管膜和胆管细胞的刷状缘膜中检测到了NaPi-IIb。相比之下,在肝细胞的基底外侧膜中检测到了PiT-1和PiT-2。我们得出结论,NaPi-IIb很可能参与了初级肝胆汁中P(i)的重吸收,因此可能在胆汁P(i)浓度的调节中起重要作用。
