Bile acid transport across the hepatocyte canalicular meni.brane (original) (raw)
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Bile acid transport across the hepatocyte canalicular membrane
The FASEB Journal
Transport of bile acids across the canalicular membrane of the hepatocyte provides the primary motive force for generation of bile flow and is rate limiting in the vectorial movement of bile acids from blood to bile. Several distinct carriers for bile acids have been defined based on physiological studies in isolated hepatocytes, membrane vesicles, hepatocyte couples, and the perfused rat liver including membrane potential-driven and ATP-dependent mechanisms. Several groups have isolated and functionally reconstituted a canalicular bile acid transport protein of M(r) approximately 110 kDa. The ATP-dependent mechanism for secretion of monovalent bile acids appears to be mediated by a yet to be identified protein of the ATP binding cassette family of transporters. However, it remains conjectural whether the ATP-dependent and membrane potential-driven components of canalicular bile acid transport are mediated by one or more transport proteins. Bile acid sulfates and glucuronides are substrates for the canalicular multispecific organic anion transporter whose activity has recently been associated with the multidrug resistance-associated protein.
Hepatic bile formation: bile acid transport and water flow into the canalicular conduit
American Journal of Physiology-Gastrointestinal and Liver Physiology, 2020
Advances in molecular biology identifying the many carrier-mediated organic anion transporters and advances in microscopy that have provided a more detailed anatomy of the canalicular conduit make updating the concept of osmotically determined canalicular flow possible. For the most part water flow is not transmembrane but via specific pore proteins in both the hepatocyte and the tight junction. These pores independently regulate the rate at which water flows in response to an osmotic gradient and therefore are determinants of canalicular bile acid concentration. Review of the literature indicates that the initial effect on hepatic bile flow of cholestatic agents such as Thorazine and estradiol 17β-glucuronide are on water flow and not bile salt export pump-mediated bile acid transport and thus provides new approaches to the pathogenesis of drug-induced liver injury. Attaining a micellar concentration of bile acids in the canaliculus is essential to the formation of cholesterol-leci...
Hepatology, 1994
B10 is an integral glycoprotein of the plasma membrane that is exclusively localized to the canalicular (apical) domain in normal rat hepatocytes but may be expressed on the basolateral (sinusoidal and lateral) membrane in pathophysiological situations. To understand how B10 may be localized to the basolateral surface, we studied the biosynthesis and transport of this apical protein. In uivo pulse-chase experiments, followed by subcellular fractionation of the liver and immunoprecipitation, showed that B10 is first synthesized as a high-mannose form of 123 kD and then matured to a complex glycosylated form of 130 kD, which peaks in the Golgi apparatus after 15 min of chase and reaches the plasma membrane with a half-time of 30 to 45 min. Analysis of the protein in plasma membrane domain fractions showed that most of the newly synthesized molecule was localized in basolateral fractions after 30 min of chase and subsequently appeared in apical fractions. After 90 min of chase, most of the radiolabeled protein had reached its steady-state apical distribution. The same experiments performed in the perfused rat liver, in which the chase can be improved, gave similar results, except that the apical distribution of the radioactive molecule was attained more quickly. Thus B10, like all apical plasma membrane proteins studied so far in hepatocytes, is first transported to the basolateral surface and then reaches the membrane of the bile canaliculi. Alterations of the transcytotic step from the basolateral to the apical surfaces may result in abnormal basolateral localization. (HEPATOLOGY 1994;19:648-655.)
Journal of Clinical Investigation, 1997
Although bile acid transport by bile duct epithelial cells, or cholangiocytes, has been postulated, the details of this process remain unclear. Thus, we performed transport studies with [ 3 H]taurocholate in confluent polarized monolayers of normal rat cholangiocytes (NRC). We observed unidirectional (i.e., apical to basolateral) Na ϩ -dependent transcellular transport of [ 3 H]taurocholate. Kinetic studies in purified vesicles derived from the apical domain of NRC disclosed saturable Na ϩ -dependent uptake of [ 3 H]taurocholate, with apparent K m and V max values of 209 Ϯ 45 M and 1.23 Ϯ 0.14 nmol/mg/10 s, respectively. Reverse transcriptase PCR (RT-PCR) using degenerate primers for both the rat liver Na ϩdependent taurocholate-cotransporting polypeptide and rat ileal apical Na ϩ -dependent bile acid transporter, designated Ntcp and ASBT, respectively, revealed a 206-bp product in NRC whose sequence was identical to the ASBT. Northern blot analysis demonstrated that the size of the ASBT transcript was identical in NRC, freshly isolated cholangiocytes, and terminal ileum. In situ RT-PCR on normal rat liver showed that the message for ASBT was present only in cholangiocytes. Immunoblots using a well-characterized antibody for the ASBT demonstrated a 48-kD protein present only in apical membranes. Indirect immunohistochemistry revealed apical localization of ASBT in cholangiocytes in normal rat liver. The data provide direct evidence that conjugated bile acids are taken up at the apical domain of cholangiocytes via the ASBT, and are consistent with the notion that cholangiocyte physiology may be directly influenced by bile acids. ( J. Clin. Invest. 1997. 100:2714-2721.) Key words: biliary epithelia • taurocholate • transport • liver • plasma membrane vesicles Preliminary portions of this work were presented at the 47th meeting of the American Association for the Study of Liver Diseases, and have been published in abstract form (1996. Hepatology. 94:897 a ).
Transport of drugs in isolated hepatocytes the influence of bile salts
Biochemical Pharmacology, 1978
The influence of bile salts on hepatic transport of drugs was studied using isolated hepatocyte suspensions. Upra~e of the organic anions, dibromosulphthalein (DBSP), indcrcyanine green (ICG) and an organic cation, N4-acetyi procainamide ethobromide (APAEB) was measured. Afte; 60 min incubation the amount of DBSP, ICG and APAEB nresent in the cells was 17. 41 and 4.5 ner cent of the added amount respectively. The release of DBSP, ICG and APAEB from the hepatocytes preincubated with the agents under study, after 60 min incubation in fresh medium was 80.5, 12.5 and 48.9 per cent of the amount initially present respectively. The presence of bile canalicular membranes in the isolated hepatocytes was demonstrated by enzymehistochemistry: 5'nucleotidase activity showed sharp branched bands over the cell surface. When bile salts were present in the incubation medium. the cellular content of DBSP, ICG and APAEB was diminished. The taurocholate concentration which caused 50 per cent of the maximal effect was 0.07mM. O.lOmM and 0.06mM in experiments with DBSP, ICG and APAEB respectively. Pharmacokinetic analysis revealed that the influence of bile salts on cellular content of the three compounds was due to inhibition of the uptake into the isolated hepatocytes, rather than stimulation of release from the cells. The hypothesis, that stimulation of biliary output of organic anions in viw is due to a modifying effect of bile salts on the canalicular membranes. instead of being the result of the increased bile flow, is not supported by this study.
Hepatic Bile Formation: Canalicular Osmolarity and Paracellular and Transcellular Water Flow
Journal of Pharmacology and Experimental Therapeutics, 2019
The purpose of this minireview is to indicate that a new paradigm is developing regarding hepatic bile flow. The focus thus far has been on the carrier-mediated transport of bile acids and other solutes, such as glutathione, which create an osmotic gradient for the transcellular and paracellular flow of water into canaliculi. In addition to the physico-chemical properties of the bile acids, which govern the osmotic gradient, data now exist that the tight junctions, governing paracellular water flow, and Aquaporin-8 water channels, governing transcellular water flow, are regulated independently. Thus, the rate of water flow into the canaliculus in response to bile acid transport is variable and determines canalicular bile acid concentration, which affects the production and solubilization of cholesterol-lecithin vesicles. These new considerations modify thinking regarding the occurrence of cholestasis and its progression and reorient the design of experimental studies that can distinguish the different determinants of bile flow.