Partitioning of bile acids into subcellular organelles and the in vivo distribution of bile acids in rat liver.

1. The subcellular distribution of conjugates of cholic acid and chenodeoxycholic acid between cytosol, nuclei, mitochondria and microsomes in rat liver has been determined. 2. The partition coefficients for the distribution of these bile acids between subcellular fractions and buffer have been measured and used to construct a compartmental model of the amounts of conjugated bile acids present in the different subcellular organelles in vivo. 3. This model indicates that a large percentage of the bile acid in the rat liver is found in the nuclear fraction; 42% of the cholic acid conjugates and 27% of the chenodeoxycholic acid conjugates. Substantial amounts of bile acid are also present in microsomes and mitochondria suggesting that published estimates of the amounts of bile acids in these fractions are underestimates. 4. The model also allows the amount of bile acid which is in free solution in cytosol to be determined; 10.9% of the cholic acid conjugates and 4.1% of the chenodeoxycholic acid conjugates in rat liver were present in this fraction. Knowlege of the amount of free bile acid allows possible roles of the cytosolic bile binding proteins to be assessed.     

Comparison of biliary excretion and metabolism of lithocholic acid and its sulfate and glucuronide conjugates in rats

Biliary excretion and biotransformation of tracer doses of [14C]lithocholic acid and its sulfate and glucuronide intravenously injected into bile-drainaged rats were compared. Biliary excretion efficiency was in the order of unconjugate sulfate glucuronide and all conjugates were completely excreted into bile within 60 min after injection. Only tracer doses of radioactivity were found in the liver and urine. About 90% of radiolabeled bile acids in bile were conjugated with taurine immediately after injection of lithocholic acid, whereas lithocholic acid-glucuronide was only partly conjugated with taurine all the time (less than 6%) and excreted into bile mainly as native compound. In the first 10 min, 66% of lithocholic acid-sulfate was conjugated with taurine and it gradually proceeded up to 87%. Hydroxylation at C-6 and C-7 positions of lithocholic acid proceeded time-dependently up to 45%. No hydroxylation was observed with lithocholic acid-sulfate or glucuronide. Differences of biliary excretion rate of these conjugates may be one of the reasons for the delayed decrease of sulfated and glucuronidated bile acids in serum after bile drainage to patients with obstructive jaundice of during the recovery of acute hepatitis than non-esterified bile acids.     

Bile acid synthesis: down-regulation by monohydroxy bile acids

The regulation of bile acid synthesis was studied in rabbits after interruption of the enterohepatic circulation by choledochoureteral anastomosis. Total daily bile acid output was 772 +/- 130 (SD) mumol/24 h, of which greater than 95% was glycocholic acid. Administration of deoxycholic or cholic acid or their conjugates (300-800 mumol) or gall-bladder bile failed to down-regulate endogenous bile acid synthesis. In contrast, chenodeoxycholic acid administration did down-regulate bile acid synthesis, but this effect was related to the formation and excretion of lithocholic acid. This observation was confirmed by the finding that i.v. infusion of 10-20 mumol of either lithocholic acid or 3 beta-hydroxy-5-cholenoic acid significantly reduced cholic acid synthesis. Thus monohydroxy bile acids, derived from either hepatic or intestinal sources, participate in the down-regulation of bile acid synthesis.     

Metabolism of lithocholic acid in the rat: formation of lithocholic acid 3-O-glucuronide in vivo

Milligram amounts of [3 beta-3H]lithocholic (3 alpha-hydroxy-5 beta-cholanoic) acid were administered by intravenous infusion to rats prepared with a biliary fistula. Analysis of sequential bile samples by thin-layer chromatography (TLC) demonstrated that lithocholic acid glucuronide was present in bile throughout the course of the experiments and that its secretion rate paralleled that of total isotope secretion. Initial confirmation of the identity of this metabolite was obtained by the recovery of labeled lithocholic acid after beta-glucuronidase hydrolysis of bile samples. For detailed analysis of biliary metabolites of [3H]lithocholic acid, pooled bile samples from infused rats were subjected to reversed-phase chromatography and four major labeled peaks were isolated. After complete deconjugation, the two major compounds in the combined first two peaks were identified as murideoxycholic (3 alpha, 6 beta-dihydroxy-5 beta-cholanoic) and beta-muricholic (3 alpha, 6 beta, 7 beta-trihydroxy-5 beta-cholanoic) acids and the third peak was identified as taurolithocholic acid. The major component of the fourth peak, after isolation, derivatization (to the methyl ester acetate), and purification by high pressure liquid chromatography (HPLC), was positively identified by proton nuclear magnetic resonance as lithocholic acid 3 alpha-O-(beta-D-glucuronide). These studies have shown, for the first time, that lithocholic acid glucuronide is a product of in vivo hepatic metabolism of lithocholic acid in the rat.     

Bile acids and bile alcohols in a child with hepatic 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase deficiency: effects of chenodeoxycholic acid treatment

Duodenal bile, urine, plasma, and feces from a child with hepatic 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase deficiency were analyzed by fast atom bombardment mass spectrometry and gas chromatography-mass spectrometry to investigate the formation and excretion of abnormal bile acids and bile alcohols. The biliary bile salts consisted of glycocholic acid (25%) and of sulfated and glycine conjugated di- and trihydroxycholenoic acids (55%), two C27 bile acids, and eleven sulfated bile alcohols (mainly tetrols, 20%), all having 3 beta,7 alpha-dihydroxy-delta 5 or 3 beta,7 alpha,12 alpha-trihydroxy-delta 5 ring structures. In plasma, sulfated cholenoic acids constituted 65% and unconjugated 3 beta,7 alpha-dihydroxy-5-cholestenoic acid 25% of the total level, 71 micrograms/ml. The urinary excretion of the former was 30.4 mg/day and that of unsaturated bile alcohol sulfates, mainly pentols, 7 mg/day. The predominant bile acid in feces was an unconjugated epimer of 3 beta,7 alpha,12 alpha-trihydroxy-5-cholenoic acid, and small amounts of cholic acid were present. The minimum total excretion was 11.3 mg/day. Treatment with chenodeoxycholic acid resulted in marked clinical improvement and normalized liver function tests. Further studies are needed to define the mechanism of action. Plasma bile acids decreased to 1.6 micrograms/ml and urinary excretion to 3.4 mg/day. Chenodeoxycholic and ursodeoxycholic acids became predominant in all samples. The fecal excretion of unsaturated cholenoic acid sulfates increased to 40 mg/day compared to 89 mg/day of saturated bile acids. The results provide further support for a defective hepatic 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase deficiency, and indicate that the 3 beta-hydroxy-delta 5 bile acids are formed via 7 alpha-hydroxycholesterol. The formation of glycocholic acid may be due to an incomplete enzyme defect or to transformation of the 3 beta-hydroxy-delta 5 structure by bacterial and hepatic enzymes during an enterohepatic circulation.     

Binding of bile acids by 100 000g supernatants from rat liver.

1. The binding of glycocholic acid, chenodeoxycholic acid and lithocholic acid to rat liver 1000 000g supernatants was studied by equilibrium dialysis. 2. The binding characteristics of the bile acids suggest that the binding components are involved in bile acid transport. 3. When mixtures of [14C]lithocholic acid and liver supernatants were eluted from columns of Sephadex G-75, a prominent peak of [14C]lithocholic acid appeared with proteins of mol.wt. approx. 40000. A second, smaller, peak of [14C]lithocholic acid was eluted with proteins of mol.wt. approx. 100000. 4. The inclusion of cholic acid, glycocholic acid or chenodeoxycholic acid in the eluting buffer decreased the amount of [14C]lithocholic acid that was eluted with the higher-molecular-weight component.     

Synthesis of bile acid monosulphates by the isolated perfused rat kidney.

Perfusion of an isolated rat kidney with labelled bile acids, in a protein-free medium, resulted in the urinary excretion of the labelled bile acid, 3% being converted into polar metabolities in 1h. These metabolities were neither glycine nor taurine conjugates, nor bile acid glucuronides, and on solovolysis yielded the free bile acid. On t.l.c. the metabolite of [24-14C]lithocholic acid had the mobility of lithocholate 3-sulphate. The principal metabolite of [24-14C]chenodeoxycholic acid had the mobility of chenodeoxycholate 7-sulphate; trace amounts appeared as chenodeoxycholate 3-sulphate. [35S]sulphate was incorporated in chenodeoxycholic acid by the kidney, resulting in a similar pattern of sulphation. No disulphate salt of chenodeoxycholic acid was detected. These findings lend support to the hypothesis that renal synthesis may account for some of the bile acid sulphates present in urine in the cholestatic syndrome in man.     

Biliary lipid secretion in the rat. The uncoupling of biliary cholesterol and phospholipid secretion from bile acid secretion by sulfated glycolithocholic acid

Glycolithocholic acid and its sulfated derivative are major metabolites of the secondary bile acid lithocholic acid in man. Both compounds are known to induce cholestasis in experimental animals. We compared the effects of these endogenous hepatotoxins on bile production and biliary lipid composition in rats with chronic biliary drainage. The compounds were administered enterally at relatively low rates (5-50% of the rats' endogenous bile acid secretion in these experiments) to simulate enterohepatic circulation. Both compounds were substantially secreted into bile (more than 90% of dose); sulfated glycolithocholic acid unchanged and glycolithocholic acid after hepatic hydroxylation predominantly in the form of glyco-beta-muricholic acid (cf. Kuipers et al. (1986) Am. J. Physiol. 251, G189-G194). Neither glycolithocholic acid nor its sulfated derivative affected the biliary excretion of endogenous bile acids or bile flow in these experiments. In spite of this, phospholipid and cholesterol secretion were significantly reduced by sulfated glycolithocholic acid but were not altered by glycolithocholic acid. Phospholipid and cholesterol secretion rapidly decreased to 25 and 50% of their initial values, respectively, at biliary output rates of sulfated glycolithocholic acid up to 2 mumol/h, and did not further decrease when this output was increased to 6 mumol/h. Small unilamellar liposomes consisting of cholesterol, [Me-14C]choline-labeled phosphatidylcholine, phosphatidylserine and [3H]cholesteryl oleate in a 5:4:1:0.1 molar ratio were employed to label intrahepatic lipid pools. Administration of sulfated glycolithocholic acid slightly reduced bile acid synthesis from [3H]cholesteryl oleate, but significantly reduced the biliary secretion of [14C]phospholipid. Glycolithocholic acid did not affect the hepatic processing of liposomal lipids. It is concluded that sulfated glycolithocholic acid at low doses causes the uncoupling of biliary lipid secretion from that of bile acids, which might represent in initiating event in sulfated glycolithocholic acid hepatotoxicity.     

Biliary copper excretion in the chicken

A series of experiments were performed to examine the nature of biliary copper excretion in the chicken. Gallbladder and hepatic bile were collected from chickens fed diets that altered copper excretion. Bile was fractionated using gel filtration chromatography and SDS-PAGE. Chicks fed the control diet excreted copper that was bound primarily to a protein aggregate of greater than 600,000 daltons and secondarily, to a 7400 dalton compound. When biliary copper levels were elevated, the distribution of copper associated with the binding compounds was changed. Both the proportion and the absolute amounts of copper in the secondary pool increased dramatically when biliary copper increased. The excretion patterns observed in the control animals are believed to represent the steady-state distribution of copper in bile. A similar distribution was observed with rat bile that was obtained under steady-state conditions. These distribution patterns differ from those reported by other investigators who examined biliary copper excretion in the rat using different experimental conditions.     

Simultaneous determination of biliary bile acids in rat: ELectron impact and ammonia chemical ionization mass spectrometric analyses of bile acids

Bile acids in the rat bile were fractionated into unconjugated, glycine- and taurine-conjugated fractions by employing piperidino-hydroxypropyl Sephadex LH-20 ion-exchange chromatography. Subsequently, these fractions were analyzed by gas-liquid chromatography (GLC) and GLC-mass spectrometry using a Silicone AN-600 column. Not only lithocholic acid, deoxycholic acid, chenodeoxycholic acid, hyodeoxycholic acid, ursodeoxycholic acid and cholic acid, but also αand β-muricholic acids were quantitatively and simultaneously detectable in conjugated and unconjugated fractions, respectively. In the unconjugated and conjugated fractions, varying amounts of the unidentified bile acid were detected upon GLC. The electron impact and ammonia chemical ionization mass spectrometric results and catalytic hydrogenation on the compound indicate that this bile acid seems to be a derivative of β-muricholic acid having a double bond in the side chain. The present method is suitable to the simultaneous and quantitative determination of unconjugated and glycine- and taurine-conjugated bile acids in the rat bile.     

Measurement of bile acid synthesis by 14CO2: the metabolism of propionyl CoA.

The relationship between 14CO2 evolution from the catabolism of [26 or 2714C] cholesterol to bile acids was studied in rats with biliary fistulae. When equal quantities of [26 or 2714C] cholesterol and [414C] cholesterol were administered, there was a significant linear relationship between 14CO2 expiration in the breath and [414C] bile acid excreted in the bile. Bile acid synthesis calculated as the ratio of 14CO2: molar specific activity of biliary cholesterol correlated highly with biliary bile acid excretion in the bile acid depleted rat. Phenobarbital, a known inducer of gamma-amino levulenic acid formation from succinyl CoA did not alter the relationship between the 14CO2 estimation of bile acid synthesis and biliary bile acid excretion, indicating that the relationship between [26 or 2714C] cholesterol side chain cleavage and 14CO2 formation was not altered. Phenobarbital, however, did cause a reduction in bile acid synthesis measured by 14CO2 evolution and by biliary bile acid excretion. The 14CO2 method underestimated bile acid excretion. 8.7% in untreated and phenobarbital treated rats respectively. Since 11% of the radioactivity which was expired as 14CO2 was isolated as bile acids, radioactivity cleaved as [1 or 314C] propionyl CoA may enter cholesterol-bile acid biosynthesis resulting in the underestimation of bile acid synthesis. To test whether radioactivity from propionyl CoA enters steroid biosynthesis [114C] propionate and [214C] propionate were given to untreated biliary fistula rats and the biliary lipids excreted in 60 hours were analyzed. Incorporation of radioactivity into cholesterol and bile acids was greater after the administration of [214C] propionate than after [114C] propionate than after [114C] propionate, suggesting that radioactivity from propionyl CoA may enter steroid biosynthesis by metabolic events in which the methylene and carboxyl carbon atoms are differentiated. Although the use of 14CO2 expiration from [26 or 2714C] cholesterol catabolism underestimates the rate of bile acid synthesis, it should have many applications because of the constant relationship between 14CO2 formation and cholesterol side chain cleavage.     

A radioimmunoassay for lithocholic acid conjugates in human serum and liver tissue

A sensitive and specific radioimmunoassay for glycine and taurine conjugates of lithocholic acid (CLCA) has been developed. ³H-glycolithocholic acid (S.A. = 17Ci/mmol) was used as tracer. Separation of free from antibody-bound bile acid was carried out using ammonium sulphate (saturated solution). The antiserum showed high specificity for both glyco and tauro conjugated lithocholate (100% cross reaction) and lithocholic acid (25% cross reaction). The sensitivity of the assay (1 pmole/tube), was adequate for measuring CLCA in peripheral blood and hepatic tissue in man.     

Effect of ursodeoxycholate on the bile flow in the rat

The relationship between the bile flow and biliary excretion rate of bile salt was studied by a continuous infusion of ursodeoxycholate and its glycine conjugate in rats. Infusion of glycoursodeoxycholate produced a higher flow rate and higher bile salt concentration than previously reported values for taurocholate. The estimated biliary transport maximum value was 2.21±0.15 μmole/min/100g body weight (mean±SD, N=13). Furthermore, a linear relation was found between the bile flow and bile salt excretion rate for a wide range of bile salt excretion with a slope value of 4.10±0.64 μl/μmole (N=10). These values were close to values previously reported for tauroursodeoxycholate. In contrast, when free ursodeoxycholate was infused, a bile salt excretion rate increased at first to a level of around 1.0 μmole/min/100g body weight with a concomitant bile flow increase, but after one hr, the bile salt excretion dropped sharply and a lower plateau of about half of the initial maximum level was established in the following hr. On the other hand, the bile flow further increased even in the second hr. Consequently, the linear relationship initially observed between the bile flow and bile salt excretion rate became gradually distorted and after one hr even the positive correlation between the two parameters was completely lost. The sharp drop in the bile salt excretion rate was found to be due to the decrease in the taurine conjugate of ursodeoxycholate in the bile. The excretion rate of free ursodeoxycholate remained at a very low level (about 0.1 μmole/min/100g body weight) throughout the experiments. The concentration of ursodeoxycholate in the liver increased sharply in the second hr corresponding to the decrease in the bile salt excretion rate. These results appear to be most easily explained by the thesis that there is a fraction of bile independent of bile salt excretion but dependent on the bile salt concentration in the hepatocyte.     

Isolation and chemical synthesis of a major, novel biliary bile acid in the common wombat (Vombatus ursinus): 15alpha-hydroxylithocholic acid

The major bile acids present in the gallbladder bile of the common Australian wombat (Vombatus ursinus) were isolated by preparative HPLC and identified by NMR as the taurine N-acylamidates of chenodeoxycholic acid (CDCA) and 15alpha-hydroxylithocholic acid (3alpha,15alpha-dihydroxy-5beta-cholan-24-oic acid). Taurine-conjugated CDCA constituted 78% of biliary bile acids, and (taurine-conjugated) 15alpha-hydroxylithocholic acid constituted 11%. Proof of structure of the latter compound was obtained by its synthesis from CDCA via a Delta14 intermediate. The synthesis of its C-15 epimer, 15beta-hydroxylithocholic acid (3alpha,15beta-dihydroxy-5beta-cholan-24-oic acid), is also reported. The taurine conjugate of 15alpha-hydroxylithocholic acid was synthesized and shown to have chromatographic and spectroscopic properties identical to those of the compound isolated from bile. It is likely that 15alpha-hydroxylithocholic acid is synthesized in the wombat hepatocyte by 15alpha-hydroxylation of lithocholic acid that was formed by bacterial 7alpha-dehydroxylation of CDCA in the distal intestine. Thus, the wombat appears to use 15alpha-hydroxylation as a novel detoxification mechanism for lithocholic acid.     

Intrabiliary glutathione hydrolysis. A source of glutamate in bile

High concentrations of glutathione (GSH) and two of its constituent amino acids, glutamate and glycine, are normally found in rat bile. To examine the role of intrabiliary GSH hydrolysis as a source of these amino acids, as well as of cystine in bile, the biliary excretion of GSH and free amino acids was measured in normal male Sprague-Dawley rats; in animals given either phenol 3,6-dibromphthalein disulfonate or diethyl maleate, inhibitors of GSH secretion into bile; and after a retrograde intrabiliary infusion of (alpha S, 5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (AT-125), an irreversible inhibitor of gamma-glutamyl transferase activity. Total concentration of amino acids in normal rat bile ranged from 4 to 7 mM and was more than double the concentration in plasma (2-3 mM). Although most amino acids were detected in bile, glutamate and glycine were the most prevalent (1.2 and 1.0 mM, respectively), followed by the branched chain amino acids valine and leucine. The administration of phenol 3,6-dibromphthalein disulfonate (180 mumol/kg, intravenous), or of diethyl maleate (1 mmol/kg, intraperitoneal), resulted in a marked decrease in the biliary excretion of GSH, as well as a decrease in the excretion of glutamate, cystine, and glycine; however, the effects of these agents were not specific for the amino acid constituents of GSH. Following retrograde intrabiliary infusion of AT-125 (10 mumol/kg), there was an immediate and sustained doubling in the rate of biliary excretion of both GSH and glutathione disulfide and a marked decrease in the rate of excretion of glutamate. Varying the dose of AT-125 (0-20 mumol/kg) resulted in an inverse linear relation between hepatic gamma-glutamyl transferase activity and the biliary excretion of intact GSH. These findings suggest that most, if not all, of the free glutamate in excreted bile is formed from the intrabiliary hydrolysis of GSH. Prior to hydrolysis within the biliary tree, substantial concentrations of GSH must be transported from liver cells into bile; minimal canalicular concentrations of this tripeptide are estimated at 5 mM.     

Measurement of faecal bile acid sulphates

A method is described for the measurement, by difference, of the sulphate fractions of faecal bile acids. A solvolysis step (for the deliberate hydrolysis of the bile acid sulphates) was added to the procedure of sample homogenisation, extraction, enzymatic hydrolysis and thin-layer chromatography. The bile acids were quantitated by gas—liquid chromatography of their methyl ester and trifluoroacetate methyl ester derivatives on 3% QF-1 columns. The total bile acid excretion in 15 control subjects was 603 ± 71 mg/24 h (x̄ ± S.E.M.). The major bile acid peaks (mg/24 h) were: lithocholic acid, without solvolysis 118 ± 26 and including solvolysis 175 ± 30; deoxycholic acid 60 ± 8 and 90 ± 18 and chenodeoxycholic acid 13 ± 7 and 15 ± 7. It was concluded that bile acid sulphates may form a considerable proportion of the total bile acids excreted in man.     

The effect of cholesterol feeding on gallbladder bile acids of the rabbit. Evidence that lithocholic acid is a primary bile acid in the rabbit.

The bile acid in gallbladder bile of rabbits fed a normal diet or one containing 2% (w/w) cholesterol have been determined by gas chromatography-mass spectrometry. The predominant bile acids in normally fed rabbits were 3 alpha, 7 alpha, 12 alpha-trihydroxy-5 beta-cholan-24-oic acid (cholic acid), 3 alpha, 12 alpha-dihydroxy-5 alpha-cholan-24-oic acid (allodeoxycholic acid) and 3 alpha, 12 alpha-dihydroxy-5 beta-cholan-24-oic acid (deoxycholic acid) with very much smaller amounts of 3 alpha-hydroxy-5 beta-cholan-24-oic acid (lithocholic acid) and 3 alpha, 12 beta-dihydroxy-5 beta-cholan-24-oic acid. In the cholesterol-fed animals the lithocholate became a predominant bile acid. Sulphated bile acids accounted for less than 1% of the total bile acids. It is proposed that lithocholic acid may be a primary bile acid in the cholesterol-fed rabbit, formed by an alternative pathway of biosynthesis involving hepatic mitochondria.     

Biliary excretion of foreign compounds. Benzene and its derivatives in the rat

1. The extent of the excretion in the bile of the rat of benzene and 21 of its simple derivatives was studied. 2. Some 16 compounds of molecular weight less than 200, and including neutral molecules (benzene and toluene), aromatic acids, aromatic amines and phenols, were injected in solution intraperitoneally into biliary-cannulated rats. Metabolites in the bile were identified and estimated. The extent of biliary excretion of these compounds was low, i.e. 0–10% of the dose in 24hr., and most appeared in the bile mainly as conjugates. 3. The biliary excretion of six conjugates of molecular weight less than 300, including three glycine conjugates, one sulphate conjugate, one glucuronic acid conjugate and two acetyl derivatives, was low (less than 3% of the dose). 4. It is concluded that simple benzene derivatives of molecular weight less than about 300 are poorly excreted in rat bile.     

Quantification of LDL cholesteryl ester contribution to biliary steroids in the rat

The proportion of LDL cholesteryl ester converted to biliary steroids was quantified in the rat. The pre-existing pool of bile was allowed to drain for 10-12 h through a bile duct cannula. A single intravenous pulse injection of LDL labelled with [3H]cholesterol linoleyl ester was made, followed by a constant infusion of the same material in order to maintain constant specific radioactivity in plasma. A new steady state was achieved within 6 h and bile samples were then collected hourly until 12 h. Although substantial amounts (53-61 micrograms/h) of cholesteryl ester were released into the liver during LDL catabolism, only a very small fraction (0.8-1.90 micrograms/h) was found in biliary steroids. The proportion of LDL cholesteryl esters contributing to biliary steroids was only 1-2%. These results perhaps explain why perturbations to accelerate bile acid excretion have no effect on plasma LDL cholesterol concentration in the rat.