Taurocholate uptake by adult rat hepatocytes in primary culture

Adult rat hepatocytes were cultured on Petri dishes for 25--30 h prior to measuring their ability to transport taurocholate. A rapid uptake of the bile acid (25 muM) was observed: about 20% was accumulated in the cells within 15 min. The taurocholate transport was saturable with an apparent Km of 28 +/- 10 muM and a maximal velocity V of 0.07 +/- 0.02 nmol/(micrograms DNA x min). Uptake was shown to be energy dependent as it was inhibited about 65% by antimycin A (20 micrograms/ml). The monohydroxylated bile acid taurolithocholate and the dihydroxylated taurochenodeoxycholate inhibited taurocholate transport to about 30 and 40% resp. of the control. The transport process was strongly dependent on sodium ions. It is concluded that the characteristics of taurocholate uptake into adult rat hepatocytes are very similar either in freshly prepared cells or in hepatocytes which are cultured on Petri dishes for 25--30 h.     

Sodium-dependent taurocholate uptake by isolated rat hepatocytes occurs through an electrogenic mechanism

The uptake mechanism for the bile salt, taurocholate, by the liver cell is coupled to sodium but the stoichiometry is controversial. A one-to-one coupling ratio would result in electroneutral transport, whereas cotransport of more than one sodium ion with each taurocholate molecule cause an electrogenic response. To better define the uptake of this bile salt, we measured the effect of taurocholate on the membrane potential and resistance of isolated rat hepatocytes using conventional microelectrode electrophysiology. The addition of 20 microM taurocholate caused transient but significant depolarization accompanied by a significant decrease in membrane resistance. The electrical effect induced by taurocholate mimicked that induced by L-alanine (10 mM), the uptake of which is known to occur through an electrogenic, sodium-coupled mechanism. The sodium dependence of taurocholate-induced depolarization was further confirmed by: (1) replacing Na+ with choline +, and (2) preincubating cells with ouabain (2 mM) or with the Na+-ionophore, gramicidin (25 micrograms/ml); both suppressed the electrogenic response. Further, cholic acid, which inhibits sodium-coupled taurocholate uptake in hepatocytes, inhibited taurocholate evoked depolarization. These results support the hypothesis that sodium-coupled taurocholate uptake by isolated hepatocytes occurs through an electrogenic process which transports more than one Na+ with each taurocholate molecule.     

Characteristics of taurine transport in rat hepatocytes in primary culture

Characteristics of taurine transport in rat hepatocytes maintained in primary culture for 24 h (cultured hepatocytes) have been investigated. The uptake of [3H] taurine by cultured hepatocytes at 2 degrees C was unsaturable, whereas that at 37 degrees C consisted of unsaturable and saturable processes. The saturable transport system was sodium-dependent and consisted of two processes with low and with high affinities. The latter process (Km, 76.9 microM; Vmax, 0.256 nmole/mg protein/min; activation energy (EA), 37.8 kcal mol-1) was competitively inhibited by 2,4-dinitrophenol and ouabain, as well as by taurine analogues such as hypotaurine and guanidinoethyl sulphonate. The Vmax and EA values found in cultured hepatocytes at 37 degrees C were 6.0 and 6.8 times higher than those found in freshly isolated hepatocytes. These results indicate that taurine transport in hepatocytes in primary culture consisted of unsaturable, and saturable, sodium and energy-dependent carrier-mediated transport processes, respectively. The facilitation of the latter transport system by primary culture of hepatocytes is also suggested.     

Absence of negative feedback control of bile acid biosynthesis in cultured rat hepatocytes

The effect of individual bile acids on bile acid synthesis was studied in primary hepatocyte cultures. Relative rates of bile acid synthesis were measured as the conversion of lipoprotein [4-14C]cholesterol into 4-14C-labeled bile acids. Additions to the culture media of cholate, taurocholate, glycocholate, chenodeoxycholate, taurochenodeoxycholate, glycochenodeoxycholate, deoxycholate, and taurodeoxycholate (10-200 microM) did not inhibit bile acid synthesis. The addition of cholate (100 microM) to the medium raised the intracellular level of cholate 10-fold, documenting effective uptake of added bile acid by cultured hepatocytes. The addition of 200 microM taurocholate to cultured hepatocytes prelabeled with [4-14C]cholesterol did not result in inhibition of bile acid synthesis. Taurocholate (10-200 microM) also failed to inhibit bile acid synthesis in suspensions of freshly isolated hepatocytes after 2, 4, and 6 h of incubation. Surprisingly, the addition of taurocholate and taurochenodeoxycholate (10-200 microM) stimulated taurocholate synthesis from [2-14C]mevalonate-labeled cholesterol (p less than 0.05). Neither taurocholate nor taurochenodeoxycholate directly inhibited cholesterol 7 alpha-hydroxylase activity in the microsomes prepared from cholestyramine-fed rats. By contrast, 7-ketocholesterol and 20 alpha-hydroxycholesterol strongly inhibited cholesterol 7 alpha-hydroxylase activity at low concentrations (10 microM). In conclusion, these data strongly suggest that bile acids, at the level of the hepatocyte, do not directly inhibit bile acid synthesis from exogenous or endogenous cholesterol even at concentrations 3-6-fold higher than those found in rat portal blood.     

Sodium-dependent phosphate and alanine transports but sodium-independent hexose transport in type II alveolar epithelial cells in primary culture

Inorganic phosphate, amino acids and sugars are of obvious importance in lung metabolism. We investigated sodium-coupled transports with these organic and inorganic substrates in type II alveolar epithelial cells from adult rat after one day in culture. Alveolar type II cells actively transported inorganic phosphate and alanine, a neutral amino acid, by sodium-dependent processes. Cellular uptakes of phosphate and alanine were decreased by about 80% by external sodium substitution, inhibited by ouabain (30 and 41%, respectively) and displayed saturable kinetics. Two sodium-phosphate cotransport systems were characterized: a high-affinity one (apparent Km = 18 microM) with a Vmax of 13.5 nmol/mg protein per 10 min and a low-affinity one (apparent Km = 126 microM) with a Vmax of 22.5 nmol/mg protein per 10 min. Alanine transport had an apparent Km of 87.9 microM and a Vmax of 43.5 nmol/mg protein per 10 min. By contrast, cultured alveolar type II cells did not express sodium-dependent hexose transport. Increasing time in culture decreased Vmax values of the two phosphate transport systems on day 4 while sodium-dependent alanine uptake was unchanged. This study demonstrated the existence of sodium-dependent phosphate and amino acid transports in alveolar type II cells similar to those documented in other epithelial cell types. These sodium-coupled transports provide a potent mechanism for phosphate and amino acid absorption and are likely to play a role in substrate availability for cellular metabolism and in regulating the composition of the alveolar subphase. The decrease in phosphate uptake with time in culture is parallel to decrease in surfactant synthesis reported in cultured alveolar type II cells, suggesting that phosphate availability for surfactant synthesis may be accomplished by a sodium-dependent phosphate uptake.     

Investigations on the sodium dependence of bile acid fluxes in the isolated perfused rat liver.

At [Na+]o = 118 mM the concentrative transfer of cholic and taurocholic acid from the perfusate into the isolated rat liver displays saturation kinetics (taurocholate: V = 299 nmol-min-1-g-1, Km = 61 muM; Cholate: V=327 nmol-min-1-g-1, Km = 436 muM). Perfusion with an isotonic sodium-free medium did not change the feature of a carrier-mediated transport but did markedly reduce V without affecting Km (taurocholate: V = 65 nmol-min-1-g-1, Km = 78 muM; cholate: V = 104 nmol-min-1-g-1, Km = 354 muM). It was experimentally assured that the observed reduction of bile salt uptake was not a consequence of regurgitation of bile salts or due to an excessive intracellular accumulation during cholestasis in the sodium-free state. The rate of taurocholate efflux is very low when compared with the rapid rate of the uptake. A stimulatory action of extracellular sodium on this pathway was also observed. Inhibition of the (Na+ + K+)-ATPase by 1 mM ouabain resulted in a decrease of bile salt uptake. Activation of the enzyme by potassium readmission to a K+-deprived liver enhanced bile salt uptake. The immediate response to alteration of the enzyme activity suggests a close association of a fraction of bile acid active transport with the sodium pump.     

Comparison of Human Hepatoma HepaRG Cells with Human and Rat Hepatocytes in Uptake Transport Assays in Order to Predict a Risk of Drug Induced Hepatotoxicity

Human hepatocytes are the gold standard for toxicological studies but they have several drawbacks, like scarce availability, high inter-individual variability, a short lifetime, which limits their applicability. The aim of our investigations was to determine, whether HepaRG cells could replace human hepatocytes in uptake experiments for toxicity studies. HepaRG is a hepatoma cell line with most hepatic functions, including a considerable expression of uptake transporters in contrast to other hepatic immortalized cell lines. We compared the effect of cholestatic drugs (bosentan, cyclosporinA, troglitazone,) and bromosulfophthalein on the uptake of taurocholate and estrone-3-sulfate in human and rat hepatocytes and HepaRG cells. The substrate uptake was significantly slower in HepaRG cells than in human hepatocytes, still, in the presence of drugs we observed a concentration dependent decrease in uptake. In all cell types, the culture time had a significant impact not only on the uptake process but on the inhibitory effect of drugs too. The most significant drug effect was measured at 4 h after seeding. Our report is among the first concerning interactions of the uptake transporters in the HepaRG, at the functional level. Results of the present study clearly show that concerning the inhibition of taurocholate uptake by cholestatic drugs, HepaRG cells are closer to human hepatocytes than rat hepatocytes. In conclusion, we demonstrated that HepaRG cells may provide a suitable tool for hepatic uptake studies.     

Aminoisobutyric acid transport in primary cultures of normal adult rat hepatocytes.

In contrast to suspensions of freshly isolated hepatic parenchymal cells (HPC), short-term monolayer cultures of HPC displayed properties of active transport for the amino acid analog aminoisobutyric acid (AIB). The uptake of AIB was inhibited by KCN and iodoacetate, failed to occur at 4 degrees, and was stimulated by glucagon. The apparent Km for AIB uptake by cultured HPC was approximately 19 mM. Glucagon did not alter the apparent Km but did increase V.     

Expression of the hepatocyte Na+/bile acid cotransporter in Xenopus laevis oocytes

The expression of the basolateral Na+/bile acid (taurocholate) cotransport system of rat hepatocytes has been studied in Xenopus laevis oocytes. Injection of rat liver poly(A)+ RNA into the oocytes resulted in the functional expression of Na+ gradient stimulated taurocholate uptake within 3-5 days. This Na(+)-dependent portion of taurocholate uptake exhibited saturation kinetics (apparent Km approximately 91 microM) and could be inhibited by 4,4'-diisothiocyano-2,2'-disulfonic acid stilbene. Furthermore, the expressed taurocholate transport activity demonstrated similar substrate inhibition and stimulation by low concentrations of bovine serum albumin as the basolateral Na+/bile acid cotransport system previously characterized in intact liver, isolated hepatocytes, and isolated plasma membrane vesicles. Finally, a 1.5- to 3.0-kilobase size-class of mRNA could be identified that was sufficient to express the basolateral Na+/taurocholate uptake system in oocytes. These results demonstrate that "expression cloning" represents a promising approach to ultimately clone the gene and to further characterize the molecular properties of this important hepatocellular membrane transport system.     

The mechanism of pantothenate transport by rat liver parenchymal cells in primary culture

The mechanism of pantothenate transport across the plasma membrane was investigated with initial velocity studies of [14C]pantothenate uptake and efflux in rat liver parenchymal cells maintained in primary culture. At 116 mM sodium, double-reciprocal plots of the initial velocity of uptake versus [pantothenate] were linear from 0.3 to 36.5 microM pantothenate and gave an apparent Km,pant of 11 +/- 2 microM. The rate of pantothenate uptake at 0 [sodium] was about 14% of the rate at 116 mM sodium, and the reciprocal of the apparent Km,pant was a linear function of [sodium]. Vmax obtained by extrapolation to infinite [pantothenate] was independent of [sodium]. Ouabain, gramicidin D, cyanide, azide, and 2,4-dinitrophenol inhibited uptake, but preloading cells with pantothenate did not. Pantothenate derivatives or carboxylic acids were only weak inhibitors of uptake. Efflux was measured in cells preloaded with [14C]pantothenate. The apparent Km for efflux was 85 +/- 29 microM, and the rate of efflux was unaffected by addition of pantothenate, sodium, ouabain, gramicidin D, or 2,4-dinitrophenol to the external medium. These features are consistent with a mechanism for pantothenate transport in which sodium and pantothenate are cotransported in a 1:1 ratio on a carrier highly specific for pantothenate; sodium decreases the apparent Km for pantothenate, and a sodium-carrier complex forms only on the intracellular side of the membrane.     

Characteristics of active transport of thyroid hormone into rat hepatocytes

Thyroid hormone uptake into primary cultured rat hepatocytes was studied using 1-min incubations with radio-iodine-labelled iodothyronines. (1) Uptake of thyroxine indicates two saturable sites apparent K_m values of 1.2 nM and 1.0 μM, and non-saturable uptake. Similar kinetics of triiodothyronine uptake have been observed. (2) The high-affinity systems of both hormones are energy-dependent (i.e., inhibited by KCN and oligomycin). It is postulated that these systems represent active transport of thyroid hormone into the cell. (3) Analysis of mutual inhibition by the substrates for the triiodothyronine and thyroxine transport systems indicates that triiodothyromine and thyroxine cross the cell membrane via separate transport systems. (4) Preincubation with ouabain resulted in a decrease in uptake of both triiodothyronine and thyroxine, suggesting that a sodium gradient is essential for this transport.     

Uptake of taurocholic acid into isolated rat-liver cells.

Binding and transport characteristics for uptake of taurocholic acid by isolated rat liver cells were studied. 1. An adsorption of taurocholate to the cell surface is terminated in less than 15 s. A Ks of 0.55 mM and a total binding capacity of 3.8 nmol/mg cell protein is determined. 2. The rate of uptake of taurocholate follows Michaelis-Menten kinetics with Km = 19 muM and V = 1.7 nmol/mg protein min. 3. There is a broad pH optimum for uptake between pH 6.5 -- 8.0. 4. The activation energy amounts to 29 kcal/mol. At high taurocholate concentration an unusual upward bend is observed in the Arrhenius plot. 5. Taurocholate uptake is competitively inhibited by taurochenodeoxycholate (Ki = 9 muM). It is noncompetitively inhibited by bromosulfophthalein (Ki = 3 muM). 6. At physiological taurocholate concentrations a 200-fold intracellular accumulation of taurocholate is observed. 7. Uptake is inhibited by about 75% by either antimycin A, carbonylcyanide m-chlorophenyl-hydrazone, ouabain. 8. Replacement of extracellular Na+ by either K+ or sucrose results in a 75% decrease of uptake. 9. It is concluded that taurocholate uptake is a carrier-mediated process, and suggested that the energy for intracellular accumulation is made available by cotransport of Na+.     

Transport functions of the liver. Lack of correlation between hepatocellular ouabain uptake and binding to (Na+ + K+)-ATPase

Ouabain uptake was studied on isolated rat hepatocytes. Hepatocellular uptake of the glycoside is saturable (Km = 348 mumol/l, Vmax = 1.4 nmol/mg cell protein per min), energy dependent and accumulative. Concentrative ouabain uptake is not present on permeable hepatocytes, Ehrlich ascites tumor cells and AS-30D ascites hepatoma cells. There is no correlation between ouabain binding to rat liver (Na+ + K+)ATPase and ouabain uptake into isolated rat hepatocytes. While ouabain uptake is competitively inhibited by cevadine, binding to (Na+ + K+)-ATPase is not affected by the alkaloid. Although the affinities of digitoxin and ouabain to (Na+ + K+)-ATPase are similar, digitoxin is 10000-times more potent in inhibiting [3H]ouabain uptake as compared to ouabain. That binding to (Na+ + K+)-ATPase appears to be no precondition for ouabain uptake was also found in experiments with plasmamembranes derived from Ehrlich ascites tumor cells and AS-30D hepatoma cells. While tumor cell (Na+ + K+)-ATPase is ouabain sensitive, the intact cells are transport deficient. Hepatic ouabain uptake might be related to bile acid transport. Several inhibitors of the bile acid uptake system also inhibit ouabain uptake.     

The effect of prostaglandin E2 (PGE2) on amino acid uptake and protein formation by lung fibroblasts

The effect of prostaglandin E2 (PGE2) on the utilization of extracellular amino acids by fetal lung fibroblasts was examined. PGE2 decreased the uptake of proline and aminoisobutyric acid (AIB) by quiescent fibroblasts in culture. The uptake of AIB by serum-activated cultures was also dramatically decreased by PGE2. The PGE2-induced decrease in the uptake of AIB was first observed at 4 h following the addition of the effector molecule to the cultures. PGE2 did not affect the uptake of leucine. The addition of cycloheximide also resulted in a decrease in the uptake of proline, similar to that induced by PGE2 at 5 X 10(-8) M. The combination of cycloheximide and PGE2 resulted in a further decrease in proline uptake. Kinetic analysis of AIB uptake following a 24-h PGE2 treatment showed an increase in the apparent Km as compared with untreated cultures. The prostaglandin remained active for at least 72 h after the addition of the molecule. Removal of the PGE2 was followed by an influx of proline into the cells. The decrease in proline uptake was associated with a decrease in the amount of intracellular free proline and an overall decrease in the amount of cell-associated protein. While PGE2 is known to increase intracellular protein degradation, the effect of PGE2 on amino acid uptake was not the result of an increase in the intracellular concentration of amino acids (transinhibition).     

Status of reduced glutathione in primary cultures of rat hepatocytes and the effect on conjugation of benzo[a]pyrene-7,8-dihydrodiol-9,10-oxide

The intracellular level of reduced glutathione (GSH) and GSH conjugation have been investigated in primary cell cultures of hepatocytes isolated from control rats, phenobarbitone (PB) and 3-methylcholanthrene (MC) treated rats. The data demonstrate that in all cell cultures the GSH concentrations show a triphasic pattern: (i) within 1 h of culture an initial marked decrease to 50% of the levels found in fresh hepatocytes; (ii) recovery of GSH concentrations to above the levels observed in fresh cells. This occurs after 6 h in culture with control cells and after 10-24 h with cells from either PB or MC treated rats and was most prominent in cells from PB-treated rats. (iii) A slow decline to between 30 and 40 nmol GSH/mg protein from 24 to 96 h in culture. Synthesis of GSH was slower in cultured cells from PB treated rats and this was confirmed by the resynthesis rates when diethylmaleate (DEM) was used to deplete GSH. The formation of GSH conjugates with racemic 7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE) was measured in control cells in suspension and after 3 and 24 h in culture. Despite the decrease in GSH concentrations observed between 1 and 4 h after culture, the conjugation rates were not decreased.     

Phorbol ester effects on hormonal responses in freshly isolated short-term incubated and cultured hepatocytes

Beta-adrenergic, alpha-1-adrenergic and glucagon stimulation of glucose release were compared between hepatocytes which were freshly isolated, incubated for 3 h in suspension or cultivated for 4 or 24 h in plastic culture flasks in the presence and absence of the protein kinase C activator 12-O-tetradecanoylphorbol-13-acetate (TPA). In contrast to the absence of an isoproterenol effect in freshly isolated hepatocytes, and increased sensitivity of glucose liberation towards isoproterenol could be observed 4 h after the start of culture, whereas the beta-receptor number was not found to be increased before 24h. TPA has no effect on isoproterenol-stimulated glucose release at all investigated conditions. The alpha-1-adrenergic responses tested by using the alpha-1-adrenergic agonist phenylephrine is blocked completely in freshly isolated hepatocytes preincubated with 10⁻⁶ M TPA. However, after 3 h incubation of hepatocytes in suspension or in primary culture, TPA had no effect on phenylephrine-stimulated glucose release. The effect of 10⁻⁹ M glucagon on glucose release from freshly isolated hepatocytes was not influenced by TPA, whereas after 90 and 180 min incubation a significant decrease could be observed. On the other hand, TPA inhibited stimulation of adenylate cyclase activity by glucagon concentrations of 10⁻⁵ M in freshly isolated hepatocytes, but not effect was found in hepatocytes incubated for 3 h in suspension or maintained for 24 h in primary culture. The different TPA effects may be an expression of changes of the accessibility of protein kinase C to TPA caused by translocation and/or intracellular activation of this enzyme at the tested experimental conditions.     

Intracellular and extracellular sites of iodination in dispersed hog thyroid cells.

Iodination and hormone synthesis has been studied in isolated hog thyroid cells in suspension. We characterized three iodination processes by use of pharmacological agents. (1) Intracellular iodination dependent on active iodide transport, which was inhibited by NaClO4 or ouabain, but not by catalase. This iodination was linear for 6h with no apparent Km for iodide of 1.5 muM, was stimulated by thyrotropin or N6O2'-dibutyryladenosine 3':5'-cyclic monophosphate, yielded mostly iodinated thyroglobulin and was efficient for tetraiodothyronine synthesis. (2) Extracellular iodination, which was sensitive to catalase, but not to NaClO4 or ouabain. This iodination plateaued after 2h and the apparent Km was 16.5 muM. This process was insensitive to thyrotropin and dibutyryl cyclic AMP. The major products were iodoprotein other then thyroglobulin and iodolipid and the yield of tetraiodothyronine was low. (3) Intracellular iodination from passively diffused iodide, which was not sensitive to inhibitors. Other characteristics of passive intracellular iodination were intermediate between active intracellular iodination and extracellular iodination. The fact that the three processes are inhibited by similar concentrations of methimazole, and their apparent Km values, when corrected for the concentrating effect of iodide trapping, are all of the same order as the Km of purified thyroid peroxidases, suggest that although their locations are different, the enzymic systems involved are identical. These results show that, besides an extracellular site of iodination, dispersed thyroid cells process an intracellular site of iodination with biochemical characteristics of physiological relevance.     

Two distinct mechanisms for taurocholate uptake in subcellular fractions from rat liver

As part of the enterohepatic circulation, hepatocytes take up bile acids from the intestines via the hepatic portal blood using a sodium-dependent carrier mechanism and resecrete the bile acids into the bile. In order to assess whether intracellular organelles are involved in the transcellular secretion of bile acids, we measured directly the ability of purified subcellular fractions of rat liver to take up taurocholate using a Millipore filtration assay. Two distinct uptake mechanisms can be discerned, one localized in the plasma membranes and the other in the Golgi and smooth microsomal fractions. Plasma membranes prepared by the method of Fleischer and Kervina (Fleischer, S., and Kervina, M. (1974) Methods Enzymol. 31, 6) take up taurocholate in a saturable manner with an apparent Vmax of 2.4 nmol min-1 mg protein-1 and a Km of 190 microM at 37 degrees C. After preincubation of the membranes with K+ ions, a sodium gradient (100 mM outside) stimulates the uptake rate by 90% with the observed Km unchanged. The stimulation is inhibited by phalloidin but not by bromosulfophthalein. Bile canalicular plasma membranes made according to Kramer et al. (Kramer, W., Bickel, U., Buscher, H. P., Gerok, W., and Kurz, G. (1982) Eur. J. Biochem. 129, 13-24) do not take up taurocholate. The transport by Golgi vesicles and smooth microsomes differs from that in the plasma membrane fraction in that it is not stimulated by a sodium gradient, has a Vmax of 12 nmol min-1 mg protein-1 and a Km of 440 microM at 37 degrees C, and is inhibited by bromosulfophthalein but not by phalloidin. Taurocholate uptake into smooth microsomes is abolished by filipin, an antibiotic that complexes with cholesterol to disrupt the membrane. This suggests that taurocholate uptake occurs into a nonendoplasmic reticulum subfraction since endoplasmic reticulum membranes contain negligible amounts of cholesterol. Little uptake was observed using rough microsomes or mitochondria. A model of transhepatic transport compatible with our observations is that taurocholate uptake into the cytoplasm occurs via the plasma membranes on the sinusoidal side of the hepatocyte; taurocholate is then taken up into smooth vesicles and the Golgi complex and is secreted into the bile by exocytosis as the vesicles fuse with the canalicular plasma membranes.