Cholic acid uptake and isolated rat hepatocytes.

Cholic acid uptake was studied in isolated rat hepatocytes using a centrifugal filtration technique to allow rapid sampling. Hepatocytes were found to adsorb as well as to transport cholic acid. The adsorption was characterized by a capacity of 24 nmol X mg cell protein-1 and an association constant of 0.59 X 103 M-1. Cholic acid uptake was linear with respect to concentration at or below 10 degree C, suggesting a unsaturable uptake process which was considered to represent simple diffusion and is quantitated by a diffusion coefficient of 1.76 pmol cholic acid X min-1 X mg protein-1 X muM-1. Above 10 degrees C the uptake curve was biphasic. After subtracting the unsaturable component from uptake rates at higher temperatures, a curve showing saturable kinetics resulted. The apparent Km and V values at 37 degrees C were calculated to be 31muM and 0.8 nmol X min-1 X mg protein-1 respectively. This saturable uptake process was temperature-dependent with an activation energy of 13 kcal X mol-1 (5.44 X 104 J X mol-1) and was inhibited by oligomycin and KCN. Countertransport was demonstrated with cholic, taurocholic and chenodeoxycholic acids. The results suggest that cholic acid is transported by an energy-dependent carrier-mediated process in addition to simple diffusion by hepatocytes, and that the postulated carrier has affinity for other bile acids.     

Hepatocellular uptake of aflatoxin B1 by non-ionic diffusion. Inhibition of bile acid transport by interference with membrane lipids

Aflatoxin B1 permeates isolated rat hepatocytes by non-ionic diffusion. Its uptake is neither saturable nor influenced by metabolic energy and not inhibited by treatment of cells with proteases. The initial rate of aflatoxin B1 uptake measured at 7 degrees C is between 40 and 50% compared to that at 37 degrees C. However, after an incubation period of 7 minutes identical equilibrium uptake is reached at both temperatures. The apparent activation energies, calculated for aflatoxin B1 uptake by Arrhenius diagrams ranged between 1.69 and 4.5 kcal/mol. A Q10 value of 1.34 was calculated for a temperature interval of 7-17 degrees C but decreased to 1.05 for the interval of 27-37 degrees C. Liposomes or lipoproteins added to the cell suspension inhibited the aflatoxin B1 uptake into hepatocytes. Liposomes mainly composed of unsaturated fatty acids bind twice as much aflatoxin B1 as those composed of saturated ones, indicating that the lipophilicity of the mycotoxin is crucial in the determination of its uptake into liver cells. At concentrations above 5 micrograms/ml, aflatoxin B1 inhibited the carrier-mediated uptake of cholic acid and of phalloidin into hepatocytes. This effect was reversible and abolished by washing the cells after preincubation with aflatoxin. In concentrations below 5 micrograms/ml the uptake of phallotoxin and cholic acid was however stimulated by 15-25%. These results indicate, that a carrier-mediated uptake into hepatocytes via the multispecific bile salt transporter is not responsible for the organoselective clearance of aflatoxins by the liver. On the other hand, the cholestatic effect of aflatoxin B1 results at least partially from the inhibition of the multispecific bile acid transport system. This inhibition may arise from affinity of aflatoxins to lipid domains of the cell membrane.     

Selective inhibition of long-chain fatty acid uptake in short-term cultured rat hepatocytes by an antibody to the rat liver plasma membrane fatty acid-binding protein

Uptake of long-chain fatty acids by short-term cultured hepatocytes was studied. Rat hepatocytes, which were cultured for 16 h on plastic dishes (3.6 X 10(6) cells/dish), were incubated with [3H]oleate in the presence of various concentrations of bovine serum albumin as a function of the concentration of unbound [3H]oleate in the medium. At 37 degrees C initial uptake velocity (V0) was saturable (Km = 9 X 10(-8) M; Vmax = 835 pmol/min per mg protein). V0 was temperature dependent with an optimum at 37 degrees C and markedly reduced at 4 degrees C and 70 degrees C. To evaluate the biologic significance of a previously isolated rat liver plasma membrane fatty acid-binding protein as putative carrier protein in the hepatocellular uptake of fatty acids, cultured hepatocytes were treated with a monospecific rabbit antibody (IgG-fraction) to this membrane protein or the IgG-fraction of the pre-immune serum as controls. Uptake kinetics of [3H]oleate in antibody pretreated short-term cultured hepatocytes revealed a depression of Vmax by 70%, while Km was only reduced by 16% compared to controls, indicating a predominant non-competitive type of inhibition. V0 of a variety of long-chain fatty acids (oleic acid, arachidonic acid, palmitic acid, stearic acid) was reduced by 56-69%, while V0 of [35S]sulfobromophthalein, [3H]cholic acid and [14C]taurocholic acid remained unaltered. These data support the concept that in the system of cultured hepatocytes, uptake of long-chain fatty acids is mediated by the rat liver plasma membrane fatty acid-binding protein.     

The effect of 3-sulphation and taurine conjugation on the uptake of chenodeoxycholic acid by rat hepatocytes

The hepatic uptake of chenodeoxycholic acid, taurochenodeoxycholic acid, chenodeoxycholic acid 3-sulphate and taurochenodeoxycholate acid 3-sulphate by isolated rat hepatocytes was examined. Taurochenodeoxycholic acid, taurochenodeoxycholic acid 3-sulphate and chenodeoxycholic acid 3-sulphate uptake occurred by a saturable, energy-dependent process while chenodeoxycholic acid uptake was predominantly non-saturable, possibly simple diffusion. Apparent Km (mumol/l) and Vmax (nmol/mg protein per min) values (mean +/- S.D.), respectively, were: chenodeoxycholic acid (saturable component), 33 +/- 6.4 and 4.8 +/- 0.6; taurochenodeoxycholic acid, 11.1 +/- 2.0 and 3.1 +/- 0.5; chenodeoxycholic acid 3-sulphate, 6.1 +/- 0.9 and 2.3 +/- 0.4; and taurochenodeoxycholic acid 3-sulphate, 5.0 +/- 0.7 and 0.9 +/- 0.15. Both conjugation with taurine and sulphation at the 3 position resulted in a reduction in the values of Km and Vmax. Uptake of each of the bile acids taurochenodeoxycholic acid, taurochenodeoxycholic acid 3-sulphate and chenodeoxycholic acid 3-sulphate was competitively inhibited by the other two, with taurochenodeoxycholic acid a potent inhibitor of both taurochenodeoxycholic acid 3-sulphate and chenodeoxycholic acid 3-sulphate uptake. Other bile acids also inhibited. Uptake was inhibited by albumin in the order chenodeoxycholic acid 3-sulphate greater than taurochenodeoxycholic acid 3-sulphate greater than taurochenodeoxycholic acid and was dependent on the extent of bile acid binding to albumin.     

Transferrin binding and iron uptake in mouse hepatocytes

Methods were developed for obtaining highly viable mouse hepatocytes in single cell suspension and for maintaining the hepatocytes in adherent static culture. The characteristics of transferrin binding and iron uptake into these hepatocytes was investigated. (1) After attachment to culture dishes for 18–24 h hepatocytes displayed an accelerating rate of iron uptake with time. Immediately after isolation mouse hepatocytes in suspension exhibited a linear iron uptake rate of 1.14·10⁵molecules/cell per min in 5 μM transferrin. Iron uptake also increased with increasing transferrin concentration both in suspension and adherent culture. Pinocytosis measured in isolated hepatocytes could account only for 10–20% of the total iron uptake. Iron uptake was completely inhibited at 4°C. (2) A transferrin binding component which saturated at 0.5 μM diferric transferrin was detected. The number of specific, saturable diferric transferrin binding sites on mouse hepatocytes was 4.4·10⁴±1.9·10⁴ for cells in suspension and 6.6·10⁴±2.3·10⁴ for adherent cultured cells. The apparent association constants were 1.23·10⁷ 1·mol^?1 and 3.4·10⁶ 1·mol^?1 for suspension and cultured cells respectively. (3) Mouse hepatocytes also displayed a large component of non-saturable transferrin binding sites. This binding increased linearly with transferrin concentration and appeared to contribute to iron uptake in mouse hepatocytes. Assuming that only saturable transferrin binding sites donate iron, the rate of iron uptake is about 2.5 molecules iron/receptor per min at 5 μM transferrin in both suspension and adherent cells and increases to 4 molecules iron/receptor per min at 10 μM transferrin in adherent cultured cells. These rates are considerably greater than the 0.5 molcules/receptor per min observed at 0.5 μM transferrin, the concentration at which the specific transferrin binding sites are fully occupied. The data suggest that either the non-saturable binding component donates some iron or that this component stimulates the saturable component to increase the rate of iron uptake. (4) During incubations at 4°C the majority of the transferrin bound to both saturable and nonsaturable binding sites lost one or more iron atoms. Incubations including 2 mM α,α′-dipyridyl (an Fe¹¹ chelator) decreased the cell associated ⁵⁹Fe at both 4 and 37°C while completely inhibiting iron uptake within 2–3 min of exposure at 37°C. These observations suggest that most if not all iron is loosened from transferrin upon interaction of transferrin with the hepatocyte membrane. There is also greater sensitivity of ⁵⁹Fe uptake compared to transferrin binding to pronase digestion, suggesting that an iron acceptor moiety on the cell surface is available to proteolysis.     

Terminal deoxynucleotidyl transferase in AKR leukemic cells and lack of relation of enzyme activity to cell cycle phase.

Cholate and taurocholate uptakes were studied in presence of albumin using isolated rat hepatocytes. Albumin decreased nonspecific binding of both bile acids and inhibited cholate uptake noncompetitively and taurocholate uptake competitively. Although different bile acids except dehydrocholate inhibited both cholate and taurocholate uptake, their relative inhibitory potency was not the same for both bile acids. Uptake of both bile acids was characterized by a saturable as well as an unsaturable process both in presence and in absence of albumin. The results suggest that both bile acids may be transported by more than one carrier and taurocholate is transported more efficiently than cholate by hepatocytes.     

Regulation of amino acid transport in L6 muscle cells: I. Stimulation of transport system a by amino acid deprivation

The regulation of amino acid transport in L6 muscle cells by amino acid deprivation was investigated. Proline uptake was Na⁺-dependent, saturable and concentrative, and was predominantly through system A. Proline uptake was inhibited by alanine, α-amino isobutyric acid (AIB), and by α-methylamino isobutyric acid, but not by lysine or valine. At 25°C, Km of proline uptake was 0.5 mM. Amino acid-deprivation resulted in a progressive increase in the rate of proline uptake, reaching up to 6-fold stimulation after 6 hours. The basal and stimulated transport were equally Na⁺-dependent, and both were inhibited by competition with the same amino acids. Kinetic analysis showed that Km decreased by a factor of 2.4 and Vmax increased 1.9-fold in deprived cells. Amino acid-deprivation did not stimulate amino acid uptake through systems other than system A. This suggests that the higher Km in proline-supplemented cells is not due to release of intracellular amino acids into unstirred layers surrounding the cells. The presence of amino acids which are substrates of system A (including AIB) during proline-deprivation, prevented stimulation of proline uptake, whereas those transported by systems Ly⁺ or L exclusively were ineffective. The stimulation of the transport-rate in deprived cells could be reversed by subsequent exposure to proline or other substrates of system A. L6 cells, deprived of proline for 6 hours, retained the stimulation of transport after detachment from the monolayers with trypsin. Uptake rates were comparable in suspended and attached cells in monolayer culture. Thus, amino acid-depreivation of L6 cells results in an adaptive increase in proline uptake, which is not due to unstirred layers but appears to be mediated by other mechanisms of selective transport regulation.     

Active transport of alpha-aminoisobutyric acid in freshly prepared rat hepatocytes

The transport of alpha-aminoisobutyric acid in freshly prepared rat liver cells was saturable and exhibited a K_t of 13.9 × 10^?3M and a_max of 28.6 umoles/ml intracellular fluid/30 min. The system required the presence of sodium and was sensitive to ouabain. Anaerobiosis, 2,4-dinitrophenol and low temperature suppressed the uptake of the amino acid. Efflux studies also indicated that the majority of the intracellular amino acid was rapidly exchangeable and therefore probably present in the cell water in a free state. It is suggested that alpha-aminoisobutyric acid is transported into isolated rat hepatocytes by an active carrier system.     

Transport of dehydroepiandrosterone and dehydroepiandrosterone sulphate into rat hepatocytes

The purpose of the present study was to characterize the transport of dehydroepiandrosterone (DHEA) and dehydroepiandrosterone sulphate (DHEAS) into hepatocytes at physiological and pharmacological concentrations. Hepatocytes were isolated from female Sprague-Dawley rats by collagenase perfusion. Uptake of [³H]DHEA and [³H]DHEAS at increasing concentrations (3.5 nM-100 μM) was measured by the rapid filtration technique at 30 s intervals up to 120 s. The uptake of DHEAS by hepatocytes was saturable (K_m = 17.0 μM; V_max = 3.7 nmol/min/mg cell protein). In contrast, a specific saturable transport system for DHEA could not be detected in rat hepatocytes. It is suggested that DHEA enters the cell by diffusion. The uptake of DHEAS could be inhibited by antimycin A, carbonylcyanide-m-chlorophenylhydrazone, and dinitrophenol (inhibitors of the mitochondrial respiratory chain), by dinitrofluorobenzene and p-hydroxymercuribenzoate (NH₂- and SH-blockers, respectively), and by monensin (Na⁺-specific ionophore). No inhibition was seen in the presence of ouabain (inhibitor of Na⁺-K⁺-ATPase) and phalloidin (inhibitor of cholate transport and actin-blocker). Interestingly, DHEAS uptake was inhibited by bile acids (cholate, taurocholate and glycocholate). Conversely, [³H]cholate uptake was strongly inhibited by DHEAS, which indicates a competition for the same carrier. Replacement of sodium ion with choline markedly decreased uptake velocity at pharmacological DHEAS concentrations. The results suggest that DHEAS uptake is a saturable, energy-dependent, carrier-mediated, partially Na⁺-dependent process, and that DHEAS may be taken up via the multispecific bile acid transport system.     

Amino acid transport by choroid plexus in vitro

Choroid plexus from mongrel cats was incubated from 1 to 120 min in artificial cerebrospinal fluid containing α-amino[1-¹⁴C]isobutyric acid. The uptake of α-amino [1-¹⁴C]isobutyric acid occurred against a concentration gradient, was saturable, dependent on metabolic energy, and inhibited by natural amino acids. These results indicate that a transport mechanism is present in choroid plexus which could serve to regulate amino acid concentration in the cerebrospinal fluid of animals.     

Effects of ranolazine on fatty acid transformation in the isolated perfused rat liver

It has been proposed that in the heart, ranolazine shifts the energy source from fatty acids to glucose oxidation by inhibiting fatty acid oxidation. Up to now no mechanism for this inhibition has been proposed. The purpose of this study was to investigate if ranolazine also affects hepatic fatty acid oxidation, with especial emphasis on cell membrane permeation based on the observations that the compound interacts with biological membranes. The isolated perfused rat liver was used, and [1-¹⁴C]oleate transport was measured by means of the multiple-indicator dilution technique. Ranolazine inhibited net uptake of [1-¹⁴C]-oleate by impairing transport of this fatty acid. The compound also diminished the extra oxygen consumption and ketogenesis driven by oleate and the mitochondrial NADH/NAD⁺ ratio, but stimulated ¹⁴CO₂ production. These effects were already significant at 20 μM ranolazine. Ranolazine also inhibited both oxygen consumption and ketogenesis driven by endogenous fatty acids in substrate-free perfused livers. In isolated mitochondria ranolazine inhibited acyl-CoA oxidation and β-hydroxybutyrate or α-ketoglutarate oxidation coupled to ADP phosphorylation. It was concluded that ranolazine inhibits fatty acid uptake and oxidation in the liver by at least two mechanisms: inhibition of cell membrane permeation and by an inhibition of the mitochondrial electron transfer via pyridine nucleotides.     

A functional, active transport system for methotrexate in freshly isolated hepatocytes.

Methotrexate transport was studied in isolated rat liver cells. The process was found to be saturable with a K_t of 2.3 × 10^?3M and Vmax of 282 nmol/g wet wt. min. The system showed a requirement for sodium ions and it was sensitive to ouabain. Metabolic inhibitors, e.g., 2,4-dinitrophenol, anaerobic conditions, and deprivation of glucose, suppressed the uptake rate. Folic acid, but not folinic acid, was slightly inhibitory. It is suggested that methotrexate is transported in isolated hepatocytes by an active, sodium dependent process.     

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.     

Amino acid transport inRhodotorula glutinis

The yeastRhodotorula glutinis was found to transport amino acids against a concentration gradient (100∶1 for 10⁻⁶ m l-lysine and 1500∶1 for 10⁻⁶ m α-aminoisobutyric acid). Anaerobically, the concentration gradients of free amino acids were occasionally higher than aerobically. The influx is saturable with an apparentK _m of 1mm forl-lysine and 2mm for α-aminoisobutyric acid. The pH optimum for AIB uptake was 5.0, the apparent activation energy between 5° and 30° was 13,200 cal/mole. Competition of an asymmetric nature among various amino acids for uptake was observed. Intracellular amino acids did not leave the cell under any conditions of incubation, short of breaking up the plasma membrane, but they showed a powerful “trans” inhibitory effect on the uptake of amino acids.     

Fatty acid effects on calcium influx and efflux in sarcoplasmic reticulum vesicles from rabbit skeletal muscle

Low concentrations of fatty acids inhibited initial Ca uptake by sarcoplasmic reticulum vesicles, the extent of inhibition varying with chain length and unsaturation in a series of C₁₄–C₂₀ fatty acids. Oleic acid was a more potent inhibitor of initial Ca uptake than stearic acid at 25°C, whereas at 5°C there was less difference between the inhibitory effects of low concentrations of these fatty acids. When the fatty acids were added later, during the phase of spontaneous Ca release that follows Ca uptake in reactions carried out at 25°C, 1–4 μM oleic and stearic acids caused Ca content to increase. This effect was due to marked inhibition of Ca efflux and slight stimulation of Ca influx. At concentrations of >4 μM, both fatty acids inhibited the Ca influx that occurs during spontaneous Ca release; in the case of oleic acid, this inhibition resembled that of initial Ca uptake at 5°C. The different effects of fatty acids at various times during Ca uptake reactions may be explained in part if alterations in the physical state of the membranes occur during the transition from the phase of initial Ca uptake to that of spontaneous Ca release.     

Characterization of conjugated and unconjugated bile acid transport via human organic solute transporter α/β

Bile acids are biosynthesized from cholesterol in hepatocytes and usually localize in the enterohepatic circulation system. This system is regulated by several transporters that are expressed in the liver and intestine. Organic solute transporter (OST) α/β, which is known as a bidirectional transporter for some organic anions, contributes to the transport of bile acids; however, the transport properties of individual bile acids are not well understood. In this study, we investigated the transport properties of five bile acids (cholic acid [CA], chenodeoxycholic acid [CDCA], deoxycholic acid [DCA], ursodeoxycholic acid [UDCA], and lithocholic acid [LCA]) together with their glycine and taurine conjugates mediated by OSTα/β. Of the unconjugated bile acids, CA, CDCA, DCA, and LCA were taken up by OSTαβ/MDCKII cells more rapidly than mock cells, but no significant increase in the uptake of UDCA was observed. On the contrary, all glycine- and taurine-conjugated bile acids showed a significant increase in the uptake by OSTαβ/MDCKII cells. Saturable OSTα/β-mediated transports of CDCA, DCA, glycochenodeoxycholic acid (GCDCA), glycodeoxycholic acid (GDCA), glycolithocholic acid (GLCA), taurochenodeoxycholic acid (TCDCA), and taurolithocholic acid (TLCA) were observed. The apparent Michaelis constants of CDCA, DCA, GCDCA, GDCA, GLCA, TCDCA, and TLCA for OSTα/β were 23.0 ± 4.0, 14.9 ± 1.9, 864.2 ± 80.7, 586.4 ± 43.2, 12.8 ± 0.5, 723.7 ± 4.8, and 23.9 ± 0.3 μM, respectively. However, the transport of other bile acids was not saturable. Our results indicate that OSTα/β has a low affinity but a high capacity for transporting bile acids.     

Uptake of biotin by human hepatoma cell line,Hep G2: A carrier-mediated process similar to that of normal liver

Little is known about the cellular and molecular regulation of the uptake process of the water-soluble vitamin biotin into liver cells, the major site of biotin utilization and metabolism. Such studies are best done using a highly viable and homogeneous cellular system that allows examination of prolonged exposure to an agent(s) or a particular condition(s) on the uptake process. Isolated hepatocytes when maintained in primary culture lose their ability to transport biotin by the specialized carrier system. The aim of the present study was, therefore, to examine the mechanism(s) of biotin uptake by the cultured human-derived liver cells, Hep G₂. Uptake to biotin by Hep G₂ cells was appreciable and linear for up to 10 min of incubation. The uptake process was Na⁺ gradient-dependent as indicated by studies of Na⁺ replacement and pretreatment of cells with gramicidin and ouabain. Biotin uptake was also dependent on both incubation temperature and intracellular energy. Unlabeled biotin and the structural analogs with free carboxyl groups (thioctic acid, desthiobiotin) but not those with blocked carboxyl group (biocytin, biotin methyl ester, and thioctic amide) caused significant inhibition of ³H-biotin uptake at 37°C but not 4°C. Initial rate of biotin uptake was saturable as a function of concentration at 37°C but was lower and linear at 4°C. Pretreatment of Hep G₂ cells with sulfhydryl group inhibitors (e.g., p-chloromer-curibenzene sulfonate) led to a significant inhibition in biotin uptake; this inhibition was effectively reversed by reducing agents (e.g., dithiothreitol). Biotin uptake was also inhibited by the membrane transport inhibitors probenecid (noncompetitively), DIDS and furosemide but not by amiloride. Pretreatment of Hep G₂ cells with valinomycin did not alter biotin uptake. The stoichiometric ratio of biotin to Na⁺ uptake in Hep G₂ cells was also determined and found to be 1:1. These findings demonstrate that biotin uptake by these cultured liver cells is mediated through a specialized carrier system that is dependent on Na⁺-gradient, temperature, and energy and transports the vitamin by an electroneutral process. These findings are similar to those seen with native liver tissue preparations and demonstrate the suitability of Hep G₂ cells for in-depth investigations of the cellular and molecular regulation of biotin uptake by the liver. © 1994 Wiley-Liss, Inc.

1 This article is a US Government work, and as such, is in the public domain in the United State of America

.     

Bile acid synthesis and secretion by rabbit hepatocytes in primary monolayer culture: comparison with rat hepatocytes

Rabbit hepatocytes isolated after liver perfusion with collagenase were maintained in primary monolayer culture for periods up to 96 h. Bile acid synthesis and secretion was measured by capillary gas-liquid chromatography and by a rapid enzymatic-bioluminescence assay. As expected from the bile acid profile of rabbit gallbladder bile, cholic acid was the only bile acid synthesized in detectable amounts and was produced at a linear rate of 170 pmol/h per mg cell protein from 24 to 96 h in culture. Ketoconazole (20 microM) inhibited cholic acid synthesis and secretion by 78%, whereas the bile acids chenodeoxycholic acid (100 microM), deoxycholic acid (100 microM) or lithocholic acid (2 microM) had no effect. When rat hepatocytes were cultured under identical conditions, the rate of bile acid synthesis was found to be only 12 pmol/h per mg cell protein, a value in agreement with previous work. The large difference in rates of bile acid synthesis between rabbit and rat hepatocytes may be due to rapid loss of cytochrome P-450 from rat hepatocytes when placed in monolayer culture. Although reportedly active in cholesterol 7 alpha-hydroxylation, form 4 cytochrome P-450 levels in rabbit hepatocytes did not correlate with rates of bile acid synthesis.     

7-Methyl bile acids: 7 beta-methyl-cholic acid inhibits bacterial 7-dehydroxylation of cholic acid and chenodeoxycholic acid in the hamster

The effect of dietary 7 beta-methyl-cholic acid [0.075% in rodent chow (6.4 mg/animal per day)] on cholesterol and bile acid metabolism was studied and compared with that of cholic acid in the hamster. Following oral administration of 7 beta-methyl-cholic acid for 3 weeks, the glycine-conjugated bile acid analog became a major constituent of gallbladder bile. Biliary cholic acid concentration decreased significantly, while that of chenodeoxycholic acid remained unchanged. Serum and liver cholesterol levels were increased by dietary 7 beta-methyl-cholic acid and by cholic acid. Hepatic microsomal HMG-CoA reductase activity was inhibited (30% of the control value) by both bile acids; cholesterol 7 alpha-hydroxylase activity was not affected. In chow controls and cholic acid-fed animals, bacterial 7-dehydroxylation of [14C]chenodeoxycholic acid and [14C]cholic acid was nearly complete. In contrast, dietary 7 beta-methyl-cholic acid effectively prevented the 7-dehydroxylation of the two primary bile acids. These results show that dietary 7 beta-methyl-cholic acid is preserved in the enterohepatic circulation and has an effect on serum and liver cholesterol concentrations similar to those produced by the naturally occurring cholic acid. 7 beta-Methyl-cholic acid is an efficient inhibitor of the bacterial 7-dehydroxylation of the primary bile acids in the hamster.     

Hepatocellular transport of cyclosomatostatins: evidence for a carrier system related to the multispecific bile acid transporter.

The uptake of the cyclopeptide c(Phe-Thr-Lys-Trp-Phe-D-Pro) (008), an analog of somatostatin with retro sequence, was studied in isolated hepatocytes. 008 is taken up by hepatocytes in a concentration-, time-, energy- and temperature- dependent manner. Since 008 is hydrophobic, it binds rapidly to liver cells. This is evident by the positive intercept at the gamma-axis in the uptake curves. At higher concentrations, a minor part of the transport occurs by diffusion at a rate of 8.307.10(-6) cm/s. This part of diffusion is measured at 4 degrees C and can be subtracted from the uptake at 37 degrees C resulting in the carrier mediated part of uptake which is saturable. Kinetic parameters for the saturable part of uptake are Km 1.5 microM and Vmax 40.0 pmol/mg per min. The transport is decreased in the absence of oxygen and in the presence of metabolic inhibitors. Uptake is accelerated at temperatures above 20 degrees C. The activation energy was determined to be 30.77 kJ/mol. The membrane potential and not a sodium gradient is the main driving force for 008 transport. Cholate (a typical substrate of the multispecific bile acid transporter) and taurocholate are mutual competitive inhibitors of 008 uptake. Phalloidin, antamanide and iodipamide, typical foreign substrates of the transporter, interfere with the uptake of 008. AS 30D ascites hepatoma cells, known to be unable to transport bile acids, phalloidin and iodipamide, are also unfit to transport 008. Interestingly, sulfobromophthalein (BSP) but not rifampicin, both foreign substrates of the bilirubin carrier, inhibits the transport of 008 in a competitive manner.