Portal blood concentrations of conjugated cholic and chenodeoxycholic acids. Relationships to bile salt synthesis in liver cells

Zonation of hepatic cytochrome P-450 expression and regulation

The CYP genes encode enzymes of the cytochrome P-450 superfamily. Cytochrome P-450 (CYP) enzymes are expressed mainly in the liver and are active in mono-oxygenation and hydroxylation of various xenobiotics, including drugs and alcohols, as well as that of endogenous compounds such as steroids, bile acids, prostaglandins, leukotrienes and biogenic amines. In the liver the CYP enzymes are constitutively expressed and commonly also induced by chemicals in a characteristic zonated pattern with high expression prevailing in the downstream perivenous region. In the present review we summarize recent studies, mainly based on rat liver, on the factors regulating this position-dependent expression and induction. Pituitary-dependent signals mediated by growth hormone and thyroid hormone seem to selectively down-regulate the upstream periportal expression of certain CYP forms. It is at present unknown to what extent other hormones that also affect total hepatic CYP activities, i.e. insulin, glucagon, glucocorticoids and gonadal hormones, act zone-specifically. The expression and induction of CYP enzymes in the perivenous region probably have important toxicological implications, since many CYP-activated chemicals cause cell injury primarily in this region of the liver.

Heterogeneous expression of cholesterol 7 alpha-hydroxylase and sterol 27-hydroxylase genes in the rat liver lobulus

We investigated the lobular localization and molecular level of expression of cholesterol 7 alpha-hydroxylase and sterol 27-hydroxylase, two key enzymes in bile acid synthesis, in isolated periportal and pericentral hepatocytes and by in situ hybridization of rat liver. Enzyme activity, mRNA, and gene transcription of cholesterol 7 alpha-hydroxylase were predominant in pericentral hepatocytes of control rats, being 7.9-, 9.9-, and 4.4-fold higher than in periportal hepatocytes, respectively. Similar localization was found for sterol 27-hydroxylase: 2.9-, 2.5-, and 1.7-fold higher enzyme activity, mRNA, and gene transcription, respectively, was found in pericentral hepatocytes. Interruption of the enterohepatic circulation with colestid resulted in upregulation of these parameters for both enzymes, as a consequence of stimulated gene expression mainly in the periportal zone. In contrast, mRNA levels and gene transcription of 3-hydroxy-3-methylglutaryl CoA reductase showed opposite lobular distribution. Selective periportal expression for the latter was enhanced, but remained local, after colestid treatment. In situ hybridization showed unambiguously that cholesterol 7 alpha-hydroxylase mRNA is localized exclusively in the pericentral zone and that sterol 27-hydroxylase mRNA is expressed preferentially in the pericentral region, though less pronounced. Administration of colestid led to expression of both genes within a larger area of the liver lobulus. In conclusion, we suggest that cholesterol 7 alpha-hydroxylase and sterol 27-hydroxylase are coordinately regulated by the bile acid gradient over the lobulus, resulting in predominant expression in the pericentral zone. Opposite lobular localization of cholesterol and bile acid synthesis provides an alternative view to interregulation of these metabolic pathways.

Effect of crilvastatin, a new cholesterol lowering agent, on unesterified LDL-cholesterol metabolism into bile salts by rat isolated hepatocytes

1. The aim of these experiments was to determine the effect of crilvastatin, a new cholesterol lowering agent, on the metabolism of unesterified low density lipoprotein (LDL)-cholesterol by rat freshly isolated hepatocytes. This preclinical model was developed as an alternative to in vivo experiments, to mimic the metabolic effects of a molecule on its target cells and to define optimal conditions for future experimentation on human hepatocytes. 2. Cells were obtained from normolipidaemic or hypercholesterolaemic rats, hypercholesterolaemia was nutritionally induced. Incubations were performed in a medium containing 600 microM taurocholate and 50 microM or 300 microM crilvastatin. 3. This molecule was shown in vitro to be carried by physiological transporters, i.e., albumin-bile salt micellar associations and LDL. Crilvastatin induced a significance increase in the synthesis and secretion by hepatocytes of bile salts resulting from the metabolism of unesterified LDL-cholesterol in both normolipidaemic and hypercholesterolaemic rats. Stimulation involved non-conjugated as well as tauro- and glyco-conjugated bile salts. These findings corroborate preliminary studies showing in vivo that crilvastatin enhances the secretion of bile acids by stimulating the uptake and incorporation of LDL-cholesterol by the liver.

Suppression of sterol 27-hydroxylase mRNA and transcriptional activity by bile acids in cultured rat hepatocytes

In previous work we have demonstrated suppression of cholesterol 7 alpha-hydroxylase by bile acids at the level of mRNA and transcription, resulting in a similar decline in bile acid synthesis in cultured rat hepatocytes [Twisk, Lehmann and Princen (1993) Biochem. J. 290, 685-691]. In view of the substantial contribution of the 'alternative' or '27-hydroxylase' route to total bile acid synthesis, as demonstrated in cultured rat hepatocytes and in vivo in humans, we here evaluate the effects of various bile acids commonly found in bile of rats on the regulation of sterol 27-hydroxylase in cultured rat hepatocytes. Addition of taurocholic acid, the predominant bile acid in rat bile, to the culture medium of rat hepatocytes resulted in a 72% inhibition of sterol 27-hydroxylase activity. The effect was exerted at the level of sterol 27-hydroxylase mRNA, showing a time- and dose-dependent decline with a maximal suppression (-75%) at 50 microM taurocholic acid after 24 h of culture. The decline in mRNA followed first-order kinetics with an apparent half-life of 13 h. Under these conditions cholesterol 7 alpha-hydroxylase mRNA (-91%) and bile acid synthesis (i.e. chenodeoxycholic and beta-muricholic acid, -81%) were also maximally suppressed. In contrast, no change was found in the level of lithocholic acid 6 beta-hydroxylase mRNA. Assessment of the transcriptional activity of a number of genes involved in routing of cholesterol towards bile acids showed similar suppressive effects of taurocholate on expression of the sterol 27-hydroxylase and cholesterol 7 alpha-hydroxylase genes (-43% and -42% respectively), whereas expression of the lithocholic 6 beta-hydroxylase gene was not affected. Taurocholic acid and unconjugated cholic acid were equally as effective in suppressing sterol 27-hydroxylase mRNA. The more hydrophobic bile acids, chenodeoxycholic acid and deoxycholic acid, also produced a strong inhibition of 57% and 76% respectively, whereas the hydrophilic beta-muricholic acid was not active. We conclude that (1) a number of bile acids, at physiological concentrations, suppress sterol 27-hydroxylase by down-regulation of sterol 27-hydroxylase mRNA and transcriptional activity and (2) co-ordinated suppression of both sterol 27-hydroxylase and cholesterol 7 alpha-hydroxylase results in inhibition of bile acid synthesis in cultured rat hepatocytes.

Bile salt secretion by hepatocytes incubated with bile salts and liposomes or low density lipoproteins

The purpose of this work was to determine the effect of exogenous unesterified cholesterol provided in either artificial liposomes or LDL on bile salt synthesis by isolated rat hepatocytes. Rates of de novo synthesis were determined in the presence of 300 or 600 microM taurocholate, 600 microM taurodehydrocholate, cholate, deoxycholate or chenodeoxycholate. There was no significant difference between the cholesterol uptake by hepatocytes when the degree of hydrophobicity of the bile salts changed (cholate vs deoxycholate or chenodeoxycholate). Compared to taurocholate, taurodehydrocholate lowered the hepatic incorporation of unesterified cholesterol for the first 60 minutes; compared to control, taurocholate stimulated the cholesterol incorporation for the first 20 minutes. A possible explanation for this finding would be an interaction between bile salts and exogenous cholesterol, depending on the kind of conjugated bile salt. Taurocholate increased the exchange of cholesterol between liposomes or LDL and hepatocyte membranes. It resulted in a significant increase of bile salt synthesis and secretion. This phenomenon was not observed with taurodehydrocholate.

Differential feedback regulation of cholesterol 7 alpha-hydroxylase mRNA and transcriptional activity by rat bile acids in primary monolayer cultures of rat hepatocytes

We have used primary monolayer cultures of rat hepatocytes to study the effects of physiological concentrations of various bile acids, commonly found in bile of normal rats, on the mechanism of regulation of cholesterol 7 alpha-hydroxylase and bile acid synthesis. Addition of taurocholic acid, the most predominant bile acid in rat bile, to the culture medium suppressed cholesterol 7 alpha-hydroxylase activity and mRNA time- and dose-dependently. The decrease in enzyme activity paralleled the changes in mRNA. Maximal suppression of cholesterol 7 alpha-hydroxylase mRNA (-91%) and enzyme activity (-89%) was observed after a 16 h incubation period with 50 microM taurocholic acid. The declines in mRNA and enzyme caused by taurocholic acid were tightly coupled and followed first-order kinetics with a half-life of 4 h. Transcriptional activity, as assessed with nuclear run-on assays, was decreased by 44% at 50 microM taurocholic acid. Mass production of bile acids (chenodeoxycholic acid and beta-muricholic acid) was inhibited to a similar extent as the cholesterol 7 alpha-hydroxylase when different concentrations of taurocholic acid were used, giving maximal inhibition (-81%) at 50 microM taurocholic acid. Glycocholic acid and unconjugated cholic acid were equally effective as taurocholic acid in suppressing cholesterol 7 alpha-hydroxylase mRNA. The more hydrophobic bile acids (chenodeoxycholic acid and deoxycholic acid) showed profound suppression of the cholesterol 7 alpha-hydroxylase mRNA by 85% and 75% respectively, whereas the other trihydroxy bile acids in rat bile, alpha- and beta-muricholic acid, were not or only marginally active. We conclude that rat bile acids, in particular the more hydrophobic ones, in concentrations commonly observed in portal blood, exert negative feedback control at the level of cholesterol 7 alpha-hydroxylase mRNA in cultured rat hepatocytes through a direct effect on the hepatocytes, and that down-regulation of transcription is only one of the mechanisms involved in this regulation.

Heterogeneity of rat liver parenchyma in cholesterol 7 alpha-hydroxylase and bile acid synthesis

Periportal and perivenous hepatocytes were isolated from rat liver by digitonin/collagenase perfusion for investigating the acinar distribution of bile acid synthesis. The specific activity of cholesterol 7 alpha-hydroxylase (EC 1.14.13.17) was 7.9-fold higher in perivenous cells than in periportal hepatocytes. Mass production of bile acids differed 4.4-fold between cultured perivenous and periportal hepatocytes. In contrast, the levels of free cholesterol in homogenates and microsomes derived from both subfractions were similar. Feeding of rats with the bile-acid-sequestering anion-exchange resin colestid resulted in a pronounced stimulation of cholesterol 7 alpha-hydroxylase activity and bile acid mass production, but decreased the perivenous/periportal ratio of both parameters. These results demonstrate that bile acid mass production, but decreased the perivenous hepatocytes, possibly owing to feedback suppression by bile acids from the enterohepatic circulation. Furthermore, the opposite acinar localization of cholesterol and bile acid biosynthesis provides an interesting alternative to current views of the regulation of their metabolic pathways.

Cholesterol and bile acid metabolism in cultures of primary rat bile ductular epithelial cells

The role of hepatocytes in bile acid and cholesterol metabolism has been extensively studied. By contrast, nothing is known about the role of bile ductular epithelial cells in cholesterol and bile acid metabolism. The purpose of the current studies was to establish whether bile ductular epithelial cells synthesize cholesterol, bile acids or both and to determine whether these cells are capable of metabolizing (hydroxylating, conjugating) bile acids. Bile ductular epithelial cells were isolated from rat liver after ligation of the common bile duct for 6 to 8 wk. Bile ductular epithelial cells were essentially free (greater than 99%) of hepatocytes and were histochemically positive (greater than 80%) for gamma-glutamyl transpeptidase activity. Cholestatic hepatocytes were simultaneously isolated and characterized with regard to their ability to synthesize and metabolize bile acids. Incubation of bile ductular epithelial cells with [14C]-acetate resulted in rapid labeling of cellular cholesterol, suggesting that these cells have a complete cholesterol biosynthetic pathway. The addition of [4-14C]-cholesterol to bile ductular epithelial cells did not lead to detectable synthesis of [14C]-bile acids. [24-14C]-Cholic acid, [24-14C]-deoxycholic acid, [24-14C]-lithocholic acid and [3H]-ursodeoxycholic acid were individually added to bile ductular epithelial cells and incubated for 24 or 48 hr. Bile acid metabolites were extracted and separated by C-18 reverse-phase high-performance liquid chromatography or thin-layer chromatography. Bile ductular epithelial cells conjugated deoxycholic acid, ursodeoxycholic acid and lithocholic acid to glycine and taurine. Surprisingly, no conjugation of cholic acid was detected. Conjugated lithocholic acid was further metabolized to highly polar metabolite(s), possibly beta-muricholic acid.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of taurocholate accumulation in cultured hepatocytes of pig, rat and man

Intracellular accumulation at 37 degrees C of 50 microM [14C]taurocholic acid by hepatocytes of pig and rat, cultured for 24 hours, and by human hepatocytes, cultured for 12 hours, reached equilibrium after an incubation time of 1 to 2 hours. Maximum capacity to accumulate taurocholate intracellularly was assessed in 3-hour incubations with increasing extracellular taurocholate concentrations. Accumulation capacity of pig and rat hepatocytes was saturated at 100 microM, while uptake by human hepatocytes slightly increased even further above this concentration. At extracellular concentrations of 100 to 500 microM, hepatocytes of these three species concentrated taurocholic acid intracellularly to between 13 and 17 nmol per mg cell protein, corresponding to an intracellular concentration which was 10-70 times higher than the added extracellular concentration. With proceeding culture age, accumulation capacity of rat and human hepatocytes declined steeply (-80% and -60%, respectively between the first and second culture day). In contrast, in cultured pig hepatocytes, this capacity was only 40% lower on the third day compared to the first day of culture. It is concluded that in cultured pig hepatocytes, the capacity to accumulate bile acids is retained for a longer time than in cultured rat and human hepatocytes.

Feedback inhibition of bile acid synthesis in cultured pig hepatocytes

Bile acid synthesis by cultured pig hepatocytes, as measured by conversion of [14C]cholesterol to bile acids, increased during the second and third day of culture. This rise was inhibited after addition of various conjugated and unconjugated bile acids in a concentration of 100 microM. It could be completely prevented by cycloheximide, indicating that de novo protein synthesis is required for the increase in bile acid formation. No effect of exogenous bile salts on LDH release to the medium or on cellular ATP content was observed, demonstrating that hepatocyte viability was not affected. During the period in which bile acid synthesis was inhibited, pig hepatocytes were able to accumulate taurocholic acid (100 microM) up to 7-18 nmol per mg cell protein (decreasing during culture time). It is concluded that feedback regulation of bile acid synthesis is exerted by direct action of bile acids on the hepatocyte.

Initial rate of sodium taurocholate uptake in isolated elutriated hepatocytes from untreated and phenobarbital-treated rats

The initial rate of sodium taurocholate uptake was measured in rat hepatocytes separated by centrifugal elutriation into five cell fractions whose difference in size was verified by flow cytometry. The hepatocytes were prepared from untreated and phenobarbital-treated rats. For untreated animals, the initial rate of taurocholate uptake at concentrations of 5 or 50 microM was the same for hepatocytes prior to fractionation and for each of the five elutriated fractions. Treatment of the animals with phenobarbital was associated with a significant increase in hepatocyte size in all fractions and caused a significant increase in the initial uptake rate. The extent of the rate increase in hepatocytes prior to fractionation was similar to that observed for each of the five hepatocyte subpopulations. Our observation indicates that phenobarbital causes a significant increase in the initial rate of sodium taurocholate uptake and suggests that large and small hepatocytes possess no inherent differences controlling the initial uptake process.

The availability of different sources of cholesterol for bile acid synthesis by cultured chick embryo hepatocytes

The availability of different sources of cholesterol for bile acid synthesis by cultured chick embryo hepatocytes was studied. Mevalonolactone was taken up by the cells and converted to cholesterol, cholesterol ester and tauroconjugates of bile acids. The addition of mevalonolactone had little effect on the conversion of endogenous cholesterol to taurocholic acid; however, taurochenodeoxycholic acid synthesis was stimulated. 25-30% of the cholesterol synthesized from mevalonolactone was converted to taurochenodeoxycholic, taurocholic and two so-far unidentified bile acids. All bile acids were secreted into the incubation medium. When cholesterol was added as mixed liposomes with phosphatidylcholine, it was taken up by the cells and converted to bile acids. At low concentrations of liposomes, the greater part of the cholesterol which was taken up by the cells was converted to bile acids. At higher concentrations, considerable amounts of cholesterol and cholesterol ester accumulated inside the cells. When mevalonolactone and cholesterol liposomes was added together, both substrates were used simultaneously for bile acids synthesis. HDL cholesterol was the best substrate tested, yielding large amounts of two, so-far, unidentified bile acids (possibly allo-bile acids) and smaller amounts of taurocholic and taurochenodeoxycholic acid. Addition of HDL suppressed the conversion of endogenous cholesterol to taurocholic acid; taurochenodeoxycholic acid synthesis, however, was stimulated.

Characterisation of rat hepatocyte monolayers for investigation of the metabolism of bile salts

Rat hepatocyte monolayers were maintained for periods up to 24 h during which time their viability was greater than 85%. Using specific radioimmunoassays, the hepatocyte monolayers were shown to synthesise conjugated cholic, chenodeoxycholic and beta-muricholic acids. Feeding the bile salt sequestrant, cholestyramine, to donor animals increased synthesis of the major bile salt conjugates by the cells. Incubation of hepatocyte monolayers with bovine serum albumin decreased total synthesis of the three bile acids measured, but increased the amount of conjugated chenodeoxycholic acid detected. In order to test whether the effect of bovine serum albumin on bile salt synthesis was due to binding of bile salts, hepatocyte monolayers were incubated with antiserum to conjugated chenodeoxycholic acid. This treatment increased conjugated chenodeoxycholic acid production but had no effect on the other bile salt conjugates. It is concluded that the increase in conjugated chenodeoxycholic acid synthesis seen with bovine serum albumin and antiserum to conjugated chenodeoxycholic acid is caused by binding of the bile salt in the medium.

The metabolism of chenodeoxycholic acid to beta-muricholic acid in rat liver

1. The synthesis of conjugated chenodeoxycholic acid and tauro-beta-muricholic acid in isolated rat hepatocytes was measured by radioimmunoassay. Production of tauro-beta-muricholic acid was linear over 4 h of incubation at 37 degrees C. The net synthesis of conjugated chenodeoxycholic acid was very much lower than that of tauro-beta-muricholic acid. 2. When hepatocytes were prepared from rats in which the enterohepatic circulation had been broken, either by feeding the bile salt sequestrant, cholestyramine or by total biliary drainage for 48 h, synthesis of tauro-beta-muricholic acid was increased compared to that in cells from control rats. Conjugated chenodeoxycholic acid accumulation during incubation of the hepatocytes was increased by cholestyramine feeding but not by total biliary drainage. These results suggest that there is a metabolic difference between the two methods of breaking the enterohepatic circulation with regard to chenodeoxycholic acid synthesis. 3. Hepatocytes prepared from rats given 1% cholesterol in the diet for at least 2 weeks synthesised significantly more tauro-beta-muricholic acid than those from control rats. The total amount of conjugated cholic, chenodeoxycholic and tauro-beta-muricholic acids synthesised by cells from cholesterol fed animals, however was not significantly different from that produced by hepatocytes from normal rats. 4. Exogenous taurochenodeoxycholic acid was metabolised to tauromuricholic acid by isolated hepatocytes. Production of tauro-beta-muricholic acid reached a maximum at a concentration of 20 microM taurochenodeoxycholic acid. The total metabolism of taurochenodeoxycholic acid, however, increased linearly up to the highest concentration measured, 50 microM. 5. The biliary content of tauro-beta-muricholic acid during total biliary drainage fell rapidly in the first 10 h and thereafter continued to decline, reaching a minimum after about 24 h. No significant rise was observed during the remainder of the experimental period. 6. It is concluded that a large proportion of the conjugated chenodeoxycholic acid synthesised by isolated hepatocytes in vitro is metabolised to tauro-beta-muricholic acid, and therefore it is necessary to take this into account when using this system to study bile salt synthesis.

The effect of dietary fat on bile salt synthesis in rat liver

The effect of dietary fat on conjugated cholic, chenodeoxycholic and tauro-beta-muricholic acid synthesis was studied using hepatocytes isolated from rats given a low-fat diet, or a low-fat diet mixed with 10% olive oil or 10% corn oil. The rats were totally biliary drained for 48 h prior to preparation of the cells in order to raise bile salt synthesis to a level which was measurable by radioimmunoassay. Synthesis of both conjugated cholic and chenodeoxycholic acid was raised in hepatocytes from rats given a fat supplement (either corn oil or olive oil) in the diet as compared to that in cells from low-fat-fed animals. Tauro-beta-muricholic acid synthesis, however, was unaffected by corn oil feeding. Production of conjugated cholic acid was increased to a greater extent when rats were given olive oil as opposed to corn oil, but these differences were not statistically significant. The conjugated cholic, chenodeoxycholic, and tauro-beta-muricholic acid and cholesterol content of bile collected at 2-h intervals during the biliary drainage of the same groups of rats was also determined. The pool size of both conjugated cholic and chenodeoxycholic acid in the enterohepatic circulation was found to be significantly decreased in rats given olive oil as compared to those given corn oil or the low-fat diet only. The pool size of tauro-beta-muricholic acid was also decreased in the olive oil-fed rats compared to the other two groups, but this difference was not statistically significant. After the pool had been drained out, animals which had received fat in the diet secreted more conjugated cholic and chenodeoxycholic acid into the bile than rats which had received the low-fat diet only. This effect was more marked when the fat given was olive oil rather than corn oil. Secretion of tauro-beta-muricholic acid into bile at this stage of biliary drainage was not changed by dietary fat supplements. Biliary cholesterol excretion was also increased in rats on diets containing 10% fat, with olive oil again having a greater effect than corn oil. The results show that supplementing the diet with fat leads to increased synthesis of conjugated cholic and chenodeoxycholic acids and biliary cholesterol secretion in the rat. The relatively more saturated fat, olive oil (85% oleate), gave a consistently larger increase than the more unsaturated, corn oil (50% linoleate), but the type of fat appeared less important than the presence of fat in the diet.