Comparison of specific binding of human epidermal growth factor (EGF) to sinusoidal and bile canalicular membranes isolated from rat liver

The binding characteristics of human epidermal growth factor (EGF) were compared between highly purified canalicular (CMV) and sinusoidal (basolateral) rat liver plasma membrane (SMV) preparations. The dissociation constants (2-3 nM) for these membranes were comparable, while the binding capacity for CMV was approximately half that for SMV. The binding capacity for CMV was too high to be accounted for only by the contamination with sinusoidal membranes, since the measurements of specific activities of various enzymes (Na+,K+-ATPase, alkaline phosphatase, and leucine aminopeptidase) indicated that the extents of the cross contamination with other membrane fractions were at most 10%. Although the physiological function of specific binding of EGF to bile canalicular membrane domain remains to be determined, it may have a role in biliary excretion of EGF. The specific binding of EGF to bile canalicular membranes from rat liver was identified for the first time.     

Liver cell plasma membrane lipids and the origin of biliary phospholipid.

The liver cell plasma membranes of fed male Wistar rats were separated into a fraction rich in bile canaliculi and the remainder of the plasma membrane. Electron-microscopically, the bile canalicular fraction consisted almost exclusively of intact bile canaliculi with thier contiguous membranes. The remaining plasma membrane fraction consisted primarily of vesicles and sheets of membranes essentially free from the bile canaliculi. The bile canalicular membrane fraction contained relatively more total lipid, cholesterol, and phospholipid, and relatively less protein. Although the phospholipid composition of the two fractions was the same, the specific activity of the bile canalicular membrane phosholipids, up to 12 h following in vivo administration of [2-3H]glycerol, was always significantly greater than that of the remaining plasma membranes, and showed a biphasic response not found in the latter. The specific activity of the phosphatidylcholine, phosphatidylethanolamine and lysophosphatidylcholine of the bile canalicular membranes rose to a peak within 40 min after administration of the label, fell sharply and then rose to a second peak after 120 min. The specific activity of the sphingomyelin and phosphatidylserine plus phosphatidylinositol of the bile canalicular membranes and of all the phospholipids of the remaining plasma membranes diphasic pattern but increased steadily to reach a maximum at 120 min. The specific activity of biliary phosphatidylcholine followed a pattern identical to that of the phosphatidylcholine, phosphatidylethanolamine and lysophosphatidylcholine of the bile canalicular membrane fraction. These results show that the average rate of turnover of phospholipid in the bile canalicular membranes is considerably greater than that in the remaining plasma membrane and other cell membrane fractions; they indicate that the phospholipid of the bile canalicular membranes exists in two or more pools, turning over a different rates; and they support the concept that biliary phospholipid is derived from the bile canalicular membrane. The results also suggest that bile canalicular phospholipid may be derived from two different sources, in contrast to the remainong plasma membrane.     

Proteolytic processing of rat liver membrane secretory component. Cleavage activity is localized to bile canalicular membranes

Membrane secretory component (mSC) mediates the transcellular movement of polymeric IgA from the sinusoidal to the bile canalicular surface of rat hepatocytes. Prior to or concomitant with arrival at the bile canalicular membrane, mSC is cleaved, producing a soluble proteolytic fragment (fSC) which is released into the bile. Conversion of mSC to fSC occurs at the cell surface of cultured rat hepatocytes (Musil, L. S., and Baenziger, J. U. (1987) J. Cell Biol. 104, 1725-1733), suggesting that vectorial release of fSC into bile in vivo may reflect localization of a mSC-specific protease to bile canalicular membranes. We have established a reconstituted system to examine the process of specific cleavage of mSC to yield fSC and to characterize the protease activity responsible. A membrane fraction highly enriched for endocytic vesicles was found to contain approximately 90% of the [35S]Cys-mSC from metabolically labeled rat liver slices but only 5% of the cellular protein. No cleavage activity was present in these vesicles. Highly enriched bile canalicular membranes were able to mediate cleavage of metabolically labeled mSC to a fragment indistinguishable from authentic fSC. In the absence of nonionic detergent, cleavage was dependent on the presence of polyethylene glycol, presumably to mediate fusion of mSC-enriched membranes with bile canalicular membranes. Following solubilization with nonionic detergent, cleavage was no longer dependent on the addition of polyethylene glycol. Cleavage of mSC was not observed with either intact or detergent-solubilized sinusoidal, microsomal, or lysosomal membranes. We have thus identified a proteolytic activity associated with bile canalicular membranes which has the properties of a membrane protein and is likely to be responsible for production of fSC in vivo. Its highly restricted localization to the bile canalicular membrane would account for the vectorial release of fSC into the bile.     

Isolation and characterization of the putative canalicular bile salt transport system of rat liver

Through labeling with the sodium salt of the photolabile bile salt derivative (7,7-azo-3 alpha,12 alpha-dihydroxy-5 beta-[3 beta-3H]cholan-24-oyl)- 2-aminoethanesulfonic acid, a bile salt-binding polypeptide with an apparent molecular weight of 100,000 was identified in isolated canalicular but not basolateral (sinusoidal) rat liver plasma membranes. This labeled polypeptide was isolated from octyl glucoside-solubilized canalicular membranes by DEAE-cellulose and subsequent wheat germ lectin Sepharose chromatography. The purified protein still contained covalently incorporated radioactive bile salt derivative and exhibited a single band with an apparent molecular weight of 100,000 on sodium dodecyl sulfate-gels. Antibodies were raised in rabbits and their monospecificity toward this canalicular polypeptide demonstrated by immunoblot analysis. No cross-reactivity was found with basolateral membrane proteins. The antibodies inhibited taurocholate uptake into isolated canalicular but not basolateral membrane vesicles. In addition, the antibodies also decreased efflux of taurocholate from canalicular vesicles. If the canalicular bile salt-binding polypeptide was immunoprecipitated from Triton X-100-solubilized canalicular membranes and subsequently deglycosylated with trifluoromethanesulfonic acid, the apparent molecular weight was decreased from 100,000 to 48,000 (sodium dodecyl sulfate-polyacrylamide gel electrophoresis). These studies confirm previous results in intact liver tissue and strongly indicate that a canalicular specific glycoprotein with an apparent molecular weight of 100,000 is directly involved in canalicular excretion of bile salts.     

Enrichment of canalicular membrane with cholesterol and sphingomyelin prevents bile salt-induced hepatic damage

These studies were undertaken to characterize the role of plasma membrane cholesterol in canalicular secretory functions and hepatocyte integrity against intravenous taurocholate administration. Cholesterol and sphingomyelin concentrations and cholesterol/phospholipid ratios were significantly increased in canalicular membranes of diosgenin-fed rats, suggesting a more resistant structure against solubilization by taurocholate. During taurocholate infusion, control rats had significantly decreased bile flow, whereas diosgenin-fed animals maintained bile flow. Maximal cholesterol output increased by 176% in diosgenin-fed rats, suggesting an increased precursor pool of biliary cholesterol in these animals. Maximal phospholipid output only increased by 43% in diosgenin-fed rats, whereas bile salt output remained at control levels. The kinetics of glutamic oxalacetic transaminase, lactic dehydrogenase, and alkaline phosphatase activities in bile showed a significantly faster release in control than in diosgenin-fed rats. After 30 min of intravenous taurocholate infusion, necrotic hepatocytes were significantly increased in control animals. Preservation of bile secretory functions and hepatocellular cytoprotection by diosgenin against the intravenous infusion of toxic doses of taurocholate was associated with an increased concentration of cholesterol and sphingomyelin in the canalicular membrane. The increase of biliary cholesterol output induced by diosgenin was correlated to the enhanced concentration of cholesterol in the canalicular membrane.     

Redistribution and fate of colchicine-induced alkaline phosphatase in rat hepatocytes: possible formation of autophagosomes whose membrane is derived from excess plasma membrane

The redistribution and fate of colchicine-induced alkaline phosphatase (ALPase) in rat hepatocytes were investigated by electron microscopic enzyme cytochemistry and biochemistry. ALPase activity markedly increased in rat hepatocytes after colchicine treatment (2.0 mg/kg body weight, intraperitoneal injection). At 20–24 h after colchicine treatment, the liver showed the highest activity of ALPase. Thereafter, ALPase activity decreased and returned to normal levels at 48 h. In normal hepatocytes from control rats, ALPase activity was seen only on the bile canalicular membrane. However, at 20–24 h after colchicine treatment, colchicine-induced ALPase was redistributed in the sinusoidal and lateral (basolateral) membranes as well as in the bile canalicular membrane. At 30–36 h after colchicine treatment, ALPase activity on the basolateral membrane gradually decreased. In contrast, ALPase in the bile canalicular membrane increased along with the enlargement of bile canaliculi, suggesting that ALPase in the basolateral membrane had been transported to the bile canalicular membrane. Furthermore, ALPase-positive vesicles, cisternae and autophagosome-like structures were frequently seen in the cytoplasm. ALPase was also positive in some lysosomal membranes. ALPase in hepatocytes at 48 h after colchicine treatment returned to almost the same location as in control hepatocytes. Altogether, it is suggested that excessively induced ALPase is at least partially retrieved by invagination of the bile canalicular membrane and then transported to lysosomes for degradation. In addition, this study indicates that excess plasma membrane might be a possible origin of autophagosomal membrane.     

Fluorescence anisotropy from diphenylhexatriene in rat liver plasma membranes

Rat livers were fractionated to obtain intracellular membrane preparations and a highly purified preparation of bile canaliculi. The fraction containing bile canaliculi was homogenized and subfractionated to give fractions representing fragments of contiguous membrane and of canalicular microvilli. The relative purity and extent of contamination of each preparation was determined. When the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene was incorporated into aliquots of each fraction at the same probe: lipid ratio and the steady-state anisotropy of its fluorescence measured, it was found that the plasma membrane preparations were much more ordered than the intracellular membrane preparations. Of the plasma membrane preparations, that containing the canalicular microvilli was the most ordered, even allowing for any contribution of contaminants. Thus the microvillus membrane of the bile canaliculus appears to be the most ordered domain of the plasma membrane of the hepatocyte. The high order in this domain may be a factor in reducing the susceptibility to bile salt damage during bile secretion, since it is this region which is exposed to high concentrations of bile salts in vivo.     

Electron microscopic cytochemical characterization of bile canaliculi and bile ducts in vitro.

Electron microscopic cytochemical localization of Mg++-activated adenosine triphosphatase (Mg++-ATPase) and 5-nucleotidase (AMPase) was investigated in bile canaliculus-rich and bile duct-containing fractions isolated from rat liver. Comparative cyochemical studies between prefixed and non-prefixed fractions revealed that the activity of both enzymes could be detected in the fractions under appropriate experimental conditions. However, the cytochemical activity of AMPase was much more sensitive to glutaraldehyde than that of Mg++-ATPase. Mg++-ATPase and AMPase reaction products were localized primarily on bile canalicular microvilli, that is, along the outer (luminal) surface of canalicular plasma membranes, but they were never observed on bile ductal microvilli. AMPase was also detectable on lateral hepatic plasma membranes. Mg++-ATPase demonstrated by the cytochemical technique described is a reliable enzyme marker for isolated bile canalicular membranes. At high magnification, Mg++-ATPase reaction product was also observed on the microfilaments surrounding isolated bile canaliculi. The possibility that the reaction product on the pericanalicular microfilaments may result from the hydrolysis of ATP byan actomyosin ATPase-like enzyme associated with these filaments is briefly discussed.     

Localization of the ecto-ATPase (ecto-nucleotidase) in the rat hepatocyte plasma membrane. Implications for the functions of the ecto-ATPase

The surface distribution of the plasma membrane Ca2+ (Mg2+)-ATPase (ecto-ATPase) in rat hepatocytes was determined by several methods. 1) Two polyclonal antibodies specific for the ecto-ATPase were used to examine the distribution of the enzyme in frozen sections of rat liver by immunofluorescence. Fluorescent staining was observed at the bile canalicular region of hepatocytes. 2) Plasma membranes were isolated from the canalicular and sinusoidal regions of rat liver. The specific activity of ecto-ATPase in the canalicular membranes was 22 times higher than that of sinusoidal membranes. The enrichment of the ecto-ATPase activity in the canalicular membrane is closely parallel to that of two other canalicular membrane markers, gamma-glutamyltranspeptidase and leucine aminopeptidase. 3) By immunoblots with polyclonal antibodies against the ecto-ATPase and the Na+,K+-ATPase, it was found that the ecto-ATPase protein was only detected in canalicular membranes and not in sinusoidal membranes, while the Na+,K+-ATPase protein was only detected in sinusoidal membranes and not in canalicular membranes. These results indicate that the ecto-ATPase is enriched in the canalicular membranes of rat hepatocytes.     

The effect of colchicine on the development of lithocholic acid-induced cholestasis. A study of the role of microtubules in intracellular cholesterol transport.

The pathogenesis of lithocholic acid (LCA-Na)-induced cholestasis involves a rapid accumulation of cholesterol in the bile canalicular membrane. Since microtubules play an important role in the intracellular transport of many materials, including cholesterol, the present study was undertaken to assess the extent to which they participate in the development of LCA-Na-induced cholestasis. Rats were pretreated with either colchicine (0.2 mumol/100 g body wt.) or saline solution 90 min before injection with LCA-Na (12 mumol/100 g body wt.). Colchicine, although not increasing bile flow by itself, significantly reduced the cholestasis caused by LCA-Na (57-32% reduction in bile flow) without affecting its metabolism into less toxic bile acids or its distribution in blood, liver or bile. Bile canalicular membranes isolated from animals treated with a combination of colchicine and LCA-Na contained less cholesterol than those treated with LCA-Na alone. However, membranes obtained from rats treated with colchicine alone contained much less cholesterol than did controls. It was found that the total amount of cholesterol accumulated within the bile canalicular membrane following LCA-Na treatment (LCA-Na + colchicine versus colchicine alone compared with LCA-Na versus controls) was unchanged by colchicine treatment. In view of these findings it is suggested that the total amount of cholesterol present within the bile canalicular membrane determines the extent of LCA-Na-induced cholestasis, LCA-Na probably moves cholesterol to the bile canalicular membrane via a microtubule independent pathway, and microtubules are unlikely to function in the transcellular transport of LCA-Na.     

Role of sodium/hydrogen exchanger isoform NHE3 in fluid secretion and absorption in mouse and rat cholangiocytes

Na+/H+ exchanger (NHE) isoforms play important roles in intracellular pH regulation and in fluid absorption. The isoform NHE3 has been localized to apical surfaces of epithelia and in some tissues may facilitate the absorption of NaCl. To determine whether the apical isoform NHE3 is present in cholangiocytes and to examine whether it has a functional role in cholangiocyte fluid secretion and absorption, immunocytochemical studies were performed in rat liver with NHE3 antibodies and functional studies were obtained in isolated bile duct units from wild-type and NHE3-/- mice after stimulation with forskolin, using videomicroscopic techniques. Our results indicate that NHE3 protein is present on the apical membranes of rat cholangiocytes and on the canalicular membrane of hepatocytes. Western blots also detect NHE3 protein in rat cholangiocytes and isolated canalicular membranes. After stimulation with forskolin, duct units from NHE3-/- mice fail to absorb the secreted fluid from the cholangiocyte lumen compared with control animals. Similar findings were observed in isolated bile duct units from wild-type mice and rats in the presence of the Na+/H+ exchanger inhibitor 5-(N-ethyl-N-isopropyl)-amiloride. In contrast, we could not demonstrate absorption of fluid from the canalicular lumen of mouse or rat hepatocyte couplets after stimulation of secretion with forskolin. These findings indicate that NHE3 is located on the apical membrane of rat cholangiocytes and that this NHE isoform can function to absorb fluid from the lumens of isolated rat and mouse cholangiocyte preparations.     

Intracellular trafficking of bile salt export pump (ABCB11) in polarized hepatic cells: constitutive cycling between the canalicular membrane and rab11-positive endosomes

The bile salt export pump (BSEP, ABCB11) couples ATP hydrolysis with transport of bile acids into the bile canaliculus of hepatocytes. Its localization in the apical canalicular membrane is physiologically regulated by the demand to secrete biliary components. To gain insight into how such localization is regulated, we studied the intracellular trafficking of BSEP tagged with yellow fluorescent protein (YFP) in polarized WIF-B9 cells. Confocal imaging revealed that BSEP-YFP was localized at the canalicular membrane and in tubulo-vesicular structures either adjacent to the microtubule-organizing center or widely distributed in the cytoplasm. In the latter two locations, BSEP-YFP colocalized with rab11, an endosomal marker. Selective photobleaching experiments revealed that single BSEP-YFP molecules resided in canalicular membranes only transiently before exchanging with intracellular BSEP-YFP pools. Such exchange was inhibited by microtubule and actin inhibitors and was unaffected by brefeldin A, dibutyryl cyclic AMP, taurocholate, or PI 3-kinase inhibitors. Intracellular carriers enriched in BSEP-YFP elongated and dissociated as tubular elements from a globular structure adjacent to the microtubule-organizing center. They displayed oscillatory movement toward either canalicular or basolateral membranes, but only fused with the canalicular membrane. The pathway between canalicular and intracellular membranes that BSEP constitutively cycles within could serve to regulate apical pools of BSEP as well as other apical membrane transporters.     

Isolation and partial characterization of a bile canalicular plasma membrane fraction from normal and regenerating rat liver.

A bile canalicular membrane fraction was isolated from 24-hour regenerating rat livers, and its properties were compared to those of homologous fractions prepared from the livers of sham-operated and unoperated controls. These canalicular membrane fractions were found to be closely related in terms of their morphology, their purity, their yield, and their qualitative protein banding profiles on sodium dodecyl sulfate-polyacrylamide gels. However, when a rigorous examination of plasma membrane enzyme marker activities was made, the regenerating liver membranes were shown to possess an increased specific activity of alkaline phosphatase and lower levels of Mg2+ ATPase and 5'-nucleotidase in comparison with control specific activity values.     

Nitric Oxide Synthase Inhibitors Do Not Attenuate Diacylglycerol or Monoacylglycerol Lipase Activities in Synaptoneurosomes

Neuron-enriched cultures and synaptoneurosomal fractions from 10 day-old rat brain contain diacylglycerol and monoacylglycerol lipase activities. Glutamate and its analogs stimulate the activities of diacylglycerol and monoacylglycerol lipases in a time-and dose-dependent manner. Stimulation of diacylglycerol and monoacylglycerol lipases by glutamate or NMDA can be blocked by MK-801 (non-competitive antagonist). Nitro L-arginine methyl ester and L-methylarginine have no effect on glutamate stimulated activities of diacylglycerol and monoacylglycerol lipases. Our studies suggest that synaptoneurosomal preparations from young rat brain are useful for obtaining important information on signal transduction.     

Effects of bile acids on actin polymerization in vitro

Bile acids are major determinants of canalicular bile secretion, and there are indications that choleretic bile acids increase bile canalicular contractions, in isolated rat hepatocytes. Therefore, we examined the influence of various bile acids on the rate of actin polymerization in vitro. The free forms of cholic acid, ursodeoxycholic acid, and chenodeoxycholic acid, as well as their taurine and glycine conjugates, were incubated with purified muscle actin, at a concentration of 100-300 nmoles/mg actin. The rate of actin polymerization was measured by viscometry and the fluorescence of the pyrene probe, linked to actin. Results showed that all bile acids slow the rate of polymerization, and that the effect was dose-dependent. However, the reduction by chenodeoxycholic acid was greater than that caused by the other bile acids. The results indicate that bile acids, particularly in high concentrations interact with actin, a finding that may be related to the increased bile canalicular contractility, and altered canalicular membrane morphology, induced by choleretic bile acids.     

Mechanism of biliary secretion of membranous enzymes: bile acids are important factors for biliary occurrence of gamma-glutamyltransferase and other hydrolases

To elucidate the mechanism of biliary occurrence of gamma-glutamyl transferase [EC 2.3.2.2] and alkaline phosphatase [EC 3.1.3.1], the effect of bile acids on the biliary level of these enzymes was studied in vivo and in vitro. Following intravenous administration of taurocholate, the activities of both enzymes in rat bile increased markedly with a concomitant increase in the excretion of the bile acid. The biliary levels of these enzymes increased to reach a maximum at 10-20 min after administration of the bile acid and decreased thereafter. Right-side-out oriented rat liver canalicular membrane vesicles which localize gamma-glutamyltransferase, aminopeptidase M and alkaline phosphatase on their outer surface (Inoue, M., Kinne, R., Tran, T., Biempica, L., & Arias, I.M. (1983) J. Biol. Chem. 258, 5183-5188) were prepared. Upon incubation of the vesicles with either intact or heat-treated bile samples, the membranous enzymes were released from the vesicles in a time-dependent manner. Incubation of these vesicles with physiological concentrations of taurocholate also solubilized these enzymes from the membranes. Affinity chromatographic analysis on concanavalin A-Sepharose revealed that the transferase thus solubilized retained the hydrophobic domain responsible for anchoring the enzyme to membrane/lipid bilayers. These results indicate that bile acid(s) excreted into the bile canalicular lumen solubilized these enzymes from the apical membrane surface of the biliary tract cells by their detergent action.     

Redox modulation of osmotic water permeability in plasma membranes isolated from roots and shoots of pea seedlings

Partitioning in a biphasic polymer system was used to isolate plasmalemma (PM) from roots and shoots of etiolated pea seedlings. The membrane preparations were used to assess the osmotic water permeability (P _os) with the stopped-flow method. The Western-blot technique was employed to determine the membrane content of the PIP-family of aquaporins, and their activity was estimated by measuring the rate of osmotic vesicle shrinking in the presence of inhibitors, HgCl₂ and AgNO₃. Monobromobimane fluorescent dye was used to determine the quantity of sulfhydryl groups in cell membranes and follow the effect of SH-oxidizing (diamide) and SH-reducing (dithiothreitol and tributylphosphine) agents on P _os of the root PM and oligomerization of aquaporins. The shoot PM was shown to combine high P _os with low aquaporin content. In the root PM, P _os was lower and the aquaporin content greatly exceeded that in the shoots. HgCl₂ and AgNO₃ did not decrease the rate of osmotic shrinking in root membrane vesicles, whereas considerably (by 40–50%) inhibited this index in the shoot membranes. Root and shoot PM preparations dramatically differed in their SH-group contents: the former exceeded the latter sixfold. When added to the homogenization medium, diamide and tributylphosphine affected the content of SH-groups and P _os in the root PM. In the roots, diamide decreased the quantity of SH-groups almost twofold and increased P _os fourfold, and the introduction of tributylphosphine produced a twofold increase in the quantity of SH-groups with only slight decrease in the P _os. Immunological analysis of membranes isolated in the presence of diamide showed that the ratio between the monomer and dimer forms of aquaporins in two membrane preparations depended on the presence of dithiothreitol in the denaturing buffer apparently because dithiothreitol exposed and reduced disulfide bonds essential for monomer interactions and inaccessible for interaction with redox modifiers of SH-groups in the membrane. Because of their inaccessibility, these modifiers could not cause the changes of P _os in the root PM produced by oxidation and reduction of SH-groups. This phenomenon is probably related to the change in the status of SH-groups in two cysteine residues at the N-end of the aquaporin loop C oriented outward into the apoplast.     

Knockdown of hepatocyte aquaporin-8 by RNA interference induces defective bile canalicular water transport

Aquaporin-8 (AQP8) water channels, which are expressed in rat hepatocyte bile canalicular membranes, are involved in water transport during bile formation. Nevertheless, there is no conclusive evidence that AQP8 mediates water secretion into the bile canaliculus. In this study, we directly evaluated whether AQP8 gene silencing by RNA interference inhibits canalicular water secretion in the human hepatocyte-derived cell line, HepG2. By RT-PCR and immunoblotting we found that HepG2 cells express AQP8 and by confocal immunofluorescence microscopy that it is localized intracellularly and on the canalicular membrane, as described in rat hepatocytes. We also verified the expression of AQP8 in normal human liver. Forty-eight hours after transfection of HepG2 cells with RNA duplexes targeting two different regions of human AQP8 molecule, the levels of AQP8 protein specifically decreased by 60-70%. We found that AQP8 knockdown cells showed a significant decline in the canalicular volume of approximately 70% (P < 0.01), suggesting an impairment in the basal (nonstimulated) canalicular water movement. We also found that the decreased AQP8 expression inhibited the canalicular water transport in response either to an inward osmotic gradient (-65%, P < 0.05) or to the bile secretory agonist dibutyryl cAMP (-80%, P < 0.05). Our data suggest that AQP8 plays a major role in water transport across canalicular membrane of HepG2 cells and support the notion that defective expression of AQP8 causes bile secretory dysfunction in human hepatocytes.     

Quantitative immunoferritin localization of leucine aminopeptidase on canine hepatocyte cell surface

Rabbit monospecific antibody against canine kidney leucine aminopeptidase (LAP) (EC.3.4.11.2) specifically immunoprecipitated kidney and also liver LAP activity from corresponding plasma membrane preparations previously solubilized with Triton X-100. Immunological specificity of the antibody was also shown by immunoblotting of LAP from canine and rat liver plasma membranes and by electrophoretic analyses of the precursor forms in MDCK cells. Canine liver was pre-fixed by perfusion with 0.6% glutaraldehyde and the dissociated liver cells were prepared without losing their polarized structure (22). They were incubated with ferritin antibody conjugates against canine kidney LAP at the saturation level, and the distribution of ferritin particles on the three surface domains of the hepatocytes was investigated quantitatively by counting ferritin particles on the cross-sectional profiles of these surfaces. Our analysis clearly indicated that LAP exists only on the bile canalicular surface, and no significant number of ferritin particles was detected either on the sinusoidal front or on the lateral surface. Ferritin particles were distributed homogeneously both on the microvillar and intermicrovillar regions. All the bile canalicular surface domains of all the hepatocytes were heavily labeled with ferritin particles, without exception.