Determination of sulfated and nonsulfated bile acids in serum by mass fragmentography

A Sep-Pak C18 cartridge was used for purification of bile acids from serum. Three kinds of deuterium labeled internal standards were required for accurate measurement of individual sulfated and nonsulfated bile acids. These internal standards were added to the serum before its application to the cartridge. Separation of sulfated and nonsulfated bile acids was performed on piperidinohydroxypropyl Sephadex LH-20 column chromatography. The nonsulfate fraction was submitted to alkaline hydrolysis, and the sulfate fraction to solvolysis followed by alkaline hydrolysis. Each fraction was converted to the hexafluoroisopropyl-trifluoroacetyl derivatives and quantitated by mass fragmentography. The recovery of each bile acid sulfate was quite satisfactory. In fasting healthy subjects the mean of total nonsulfated bile acids in serum was 1.324 micrograms/ml, and that of total sulfated bile acids was 0.450 micrograms/ml. Sulfated lithocholic acid comprised a large part of sulfated bile acids in healthy subjects.     

Electrophysiological evidence for detection and discrimination of pheromonal bile acids by the olfactory epithelium of female sea lampreys (<Emphasis Type="Italic">Petromyzon marinus</Emphasis>)

Electro-olfactograms were used to determine sensitivity and specificity of olfactory organs of female sea lampreys (Petromyzon marinus) to four bile acids: 3-keto petromyzonol sulfate and 3-keto allocholic acid from spermiating males and petromyzonol sulfate and allocholic acid from larvae. Spermiating male bile acids are thought to function as a mating pheromone and larval bile acids as a migratory pheromone. The response threshold was 10^–12 mol l^–1 for 3-keto petromyzonol sulfate and 10^–10 mol l^–1 for the other bile acids. At concentrations above 10^–9 mol l^–1, the sulfated bile acids showed almost identical potency, as did the non-sulfated bile acids. The two sulfated bile acids were more potent than the two non-sulfated ones. In addition, 3-keto petromyzonol sulfate and water conditioned with spermiating males induced similar concentration-response curves and response thresholds. Cross-adaptation experiments demonstrated that the sulfated and non-sulfated bile acids represent different odors to the olfactory epithelium of females. Further exploration revealed that 3-keto petromyzonol sulfate represents a different odor than petromyzonol sulfate, while 3-keto allocholic acid and allocholic acid represent the same odor. Results indicate that male-specific bile acids are potent and specific stimulants to the female olfactory organ, supporting the previous hypothesis that these bile acids function as a pheromone.Abbreviations 3kACA 3-keto allocholic acid - 3kPZS 3-keto petromyzonol sulfate - ACA allocholic acid - ANOVA analysis of variance - ELISA enzyme-linked immunosorbent assay - EOG electro-olfactogram - PIR percent initial response - PZS petromyzonol sulfate - SMW spermiating male washings     

A bile alcohol sulfate as a major component in the bile of the small skate (Raja erinacea)

The nature of bile alcohols and bile acids in gall-bladder and hepatic bile from perfused livers of the small skate (Raja erinacea) has been investigated. The main bile alcohol sulfate was isolated by thin-layer chromatography and analyzed by fast atom bombardment mass spectrometry and 13C NMR. Following solvolysis and purification on Lipidex-DEAP, the bile alcohol profile was measured by capillary gas-liquid chromatography-electron impact mass spectrometry. Based on these studies and on comparison with authentic scymmnol sulfate and scymnol, the main bile alcohol was identified as 5 beta-cholestane-3 alpha,7 alpha,12 alpha,24 xi,26,27-hexol sulfate. The mean +/- SD concentration in gallbladder bile from five different skates was 24.6 +/- 8.7 mmol/l. Only 0.1 mmol/l of cholic acid and its conjugates was found in a pool of skate bile. The main bile alcohol sulfate in the bile of the small skate seems to be a metabolic end product, present in a concentration comparable to that of bile salts in mammals.     

A novel sulfatase from Pseudomonas testosteroni hydrolyzing lithocholic acid sulfate.

Pseudomonas testosteroni ATCC 11996 was found to produce a novel bile acid sulfate sulfatase that hydrolyzes the sulfate ester bond in lithocholic acid sulfate (LCA-S). The enzyme synthesis was induced by several kinds of bile acids including LCA-S. Mn2+ functioned as an essential component for the enzyme synthesis and SO4(2-) suppressed it. This sulfatase hydrolyzes LCA-S to isolithocholic acid and sulfuric acid with inversion of alpha- to beta-configuration of the hydroxyl group at the third position of lithocholic acid.     

Specificity of bile salt sulfatase activity from Clostridium sp. strains S1.

Clostridium sp. strain S1, an unnamed bile acid-desulfating strain from rat intestinal microflora (S.M. Huijghebaert, J. A. Mertens, and H. J. Eyssen, Appl. Environ. Microbiol. 43:185-192, 1982), was examined for its ability to desulfate different bile acid sulfates and steroid sulfates in growing cultures. Clostridium sp. strain S1 desulfated the 3 alpha-monosulfates of chenodeoxycholic, deoxycholic, and cholic acid, but not their 7 alpha- or 12 alpha-monosulfates. Among the 3-sulfates of the 5 alpha- and 5 beta-bile acids, only bile acid-3-sulfates with an equatorial sulfate group were desulfated. Hence, Clostridium sp. strain S1 desulfated the 3-sulfates of bile acids with a 3 alpha, 5 beta-, a 3 beta, 5 alpha- or a 3 beta, delta 5-structure. In contrast, the bile acid-3-sulfates with a 3 beta, 5 beta- or a 3 alpha, 5 alpha-structure were not desulfated. In addition, Clostridium sp. strain S1 did not hydrolyze the equatorial 3-sulfate esters of C19 and C21 steroids and cholesterol or the phenolic 3-sulfate esters of estrone and estradiol. 23-Nordeoxycholic acid with a C-23 carboxyl group was also not desulfated, in contrast to the 5 beta-bile acid 3 alpha-sulfates with a C-24 or C-26 carboxyl group. Therefore, the specificity of the sulfatase of Clostridium sp. strain S1 is related to the location of the sulfate group on the bile acid molecule, the equatorial orientation of the sulfate group, and the structure of the C-17 side chain, its carboxyl group, and chain length.     

Bile acid sulfates. II. Formation, metabolism, and excretion of lithocholic acid sulfates in the rat

Sulfate esterification has been shown previously to be a prominent feature of lithocholate metabolism in man. These studies were undertaken to ascertain whether this metabolic pathway is also present in rats, and to investigate the physiological significance of bile acid sulfate formation. Lithocholic acid-24-(14)C was administered to bile fistula rats, and sulfated metabolites were identified in bile by chromatographic and appropriate degradative procedures. They constituted only a small fraction (2-9%) of the total metabolites but a more significant fraction (about 20%) of the secreted monohydroxy bile acids, most of the lithocholate having been hydroxylated by the rat liver. When sulfated glycolithocholate was administered orally, it was absorbed from the intestine without loss of the sulfate, presumably by active transport, and secreted intact into the bile. In comparison with non-sulfated lithocholate, an unusually large fraction (24%) of the sulfated bile acid was excreted in the urine, and fecal excretion took place more rapidly. Both the amino acid and sulfate moieties were extensively removed prior to excretion in the feces. Hydroxylation of bile acid sulfates or sulfation of polyhydroxylated bile acids did not occur to any great extent, if at all.     

Occurrence of sulfated 5alpha-cholanoates in rat bile

Bile acids in bile from male and female rats with cannulated bile ducts have been analyzed by repetitive scanning gas-liquid chromatography-mass spectrometry after initial fractionation of conjugate classes on diethylaminohydroxypropyl Sephadex LH-20. Sex differences were observed in the amounts and types of bile acids in the sulfate fraction. The proportion of total bile acids excreted as sulfates was higher in female (0.9-1.3%) than in male (0.1-0.2%) rats. Most of the sulfated bile acids had a 5alpha configuration, allochenodeoxycholic acid being the major compound in bile from female rats. This bile acid was also present in the nonsulfate fraction but could not be found in bile from male rats. The results indicate that gas-liquid chromatography-mass spectrometry has to be used to provide sufficient specificity in the bile acid analyses. Thus, compounds from the sulfate fraction having the retention times of cholic and chenodeoxycholic acid derivatives were found to be due to derivatives of the 3beta,5alpha-isomers of these bile acids.     

Study of HDL2-dependent synthesis of bile acids in culture of rabbit hepatocytes: effects of oxidized cholesterol derivatives

The effect of individual oxysterols--products of auto-oxidation of cholesterol on bile acid synthesis by cultivated rabbit hepatocytes was studied. Relative rates of bile acid synthesis were measured as the conversion of 4-14C cholesterol-HDL2 into total 4-14C labeled bile acids. 7 beta-hydroxycholesterol and 3,5-cholestane-7-dione strongly inhibited bile acid synthesis at concentrations 1-10 micrograms/ml. These data support the hypothesis that oxidized cholesterol derivatives accelerate the development of hypercholesterolemia in rabbits fed on cholesterol containing diet.     

Hepatic metabolism of short-chain bile acids. Inversion of the 3-hydroxyl group of isoetianic acid (3 beta-hydroxy-5 beta-androstane-17 beta-carboxylic acid) by the adult rat

The stereospecificity of mechanisms for hepatic transport of short-chain bile acids has been examined by following the hepatic metabolism and biliary secretion of 3 beta-hydroxy-5 beta-androstane-17 beta-carboxylic acid (isoetianic acid) administered in two different labeled forms to rats prepared with an external biliary fistula. While 93% of the administered [2,2,4,4-3H]isoetianic acid was recovered in bile after 20 h, only 18% of a similar dose of [3 alpha-3H]isoetianic acid was secreted in bile over the same time period. The recovered radioactivity of the latter compound was mainly associated with bile water. With the [2,2,4,4-3H]isoetianic acid, the bulk of the biliary isotope was determined to be in the form of two glucuronide conjugates. Spectral analysis identified these metabolites as the hydroxyl-linked (major) and carboxyl-linked (minor) beta-glucuronides, not of the 3 beta-hydroxy compound administered, but of 3 alpha-hydroxy-5 beta-androstane-17 beta-carboxylic acid (etianic acid), i.e., the products of hydroxyl group inversion. It is concluded that isoetianic acid is efficiently cleared from plasma and conjugated with glucuronic acid after its epimerization to etianic acid. The prevalent, but not complete, loss of the 3-tritium atom and the retention of the 2- and 4-tritium atoms probably indicates a 3-oxo-5 beta-androstane-17 beta-carboxylic acid intermediate with partial return of the label via a limited labeled pool of reduced nicotinamide cofactor.     

Deuterium transfer from [1,1-2-H] ethanol during metabolism of bile acids and cyclohexanone in the isolated perfused rat liver.

Deuterium transfer from [1,1-2-H]ethanol (95 atoms % excess) to reducible substrates was studied in the isolated perfused rat liver. The dueterium excess in cyclohexanol formed from cyclohexanone was somewhat lower (49 atoms%) than found under conditions in vivo, and this was also true of the deuterium excess in lithocholic acid formed from 3-oxo-5beta-cholanoic acid. These results may reflect a slower rate of ethanol oxidation in the isolated organ than in vivo. Cycloserine decreased the dueterium transfer to both substrates, whereas addition of lactate and malate resulted in an increased deuterium excess in cyclohexanol and a decreased deuterium excess in lithocholic acid. Addition of heavy water to the perfusion fluid resulted in labelling at C-3 of lithocholic acid formed from 3-oxo-5beta-cholanoic acid, and at C-3, C-4 and C-5 of 3alpha-hydroxy-5alpha-cholanoic acid formed from 3-oxo-4-cholenoic acid. The deuterium excess of hydrogens derived from NADPH (at C-3 and C-5) was approximately the same as that of hydrogen derived directly from water (at C-4). Thus, the hydrogen of NADPH is extensively exchanged with protons of water, which explains the dilution of deuterium with protium during the transfer from [1,1-2-H]ethanol via NADPH to the bile acids. The labelling at C-5 in the reduction of the 4,5-double bond indicates that different pools of NADPH are used for reduction of this double bond and the 3-oxo group, since in a previous study it was shown that deuterium is transferred from [1,1-2-H]ethanol only in the latter reaction.     

The effect of bile salts on human vascular endothelial cells

The uptake and release of radiochromium from adult human vascular endothelial cells in culture was employed to determine the relative toxicity of different bile salts. Endothelial cells after pre-incubation with 51Cr for 18 h were incubated with bile salts for 24 h and percentage chromium release was taken as a measure of toxicity to cells. Lithocholic acid (LC) (potassium salt) was cytotoxic at concentrations greater than 50 microM. However, LC glucuronide, sulfate and the beta-epimer were progressively less toxic with toxicity seen at concentrations of 60, 110 and 180 microM, respectively. The greatest cytotoxic effect was observed with glycolithocholic acid (GLC) (potassium salt) which was toxic at every concentration tested (20-200 microM). Sulfation abolished the toxic effect of GLC. At the concentrations employed for the assay (between 20 and 240 microM) GLC sulfate (disodium salt), taurolithocholic acid sulfate (disodium salt), cholic acid (sodium salt), glycocholic acid (sodium salt), deoxycholic acid (sodium salt) and ursodeoxycholic acid (sodium salt) were not cytotoxic. The 51Cr release cytotoxicity assay was validated with lactate dehydrogenase leakage from endothelial cells with a good correlation (r = 0.87). These data confirm in a human cellular system that LC and its conjugates were the most toxic of the bile salts tested and explains its pathophysiological importance in hepatobiliary disease. It also suggests that biotransformation by either sulfation or beta-epimerisation of bile salts especially of LC, as occurs in patients with intrahepatic or extrahepatic biliary obstruction or severe cholestasis, is hepatoprotective.     

Physicochemical and physiological properties of 5alpha-cyprinol sulfate,the toxic bile salt of cyprinid fish

5alpha-Cyprinol sulfate was isolated from bile of the Asiatic carp, Cyprinus carpio. 5alpha-Cyprinol sulfate was surface active and formed micelles; its critical micellization concentration (CMC) in 0.15 M Na+ using the maximum bubble pressure device was 1.5 mM; by dye solubilization, its CMC was approximately 4 mM. At concentrations >1 mM, 5alpha-cyprinol sulfate solubilized monooleylglycerol efficiently (2.1 molecules per mol micellar bile salt). When infused intravenously into the anesthetized rat, 5alpha-cyprinol sulfate was hemolytic, cholestatic, and toxic. In the isolated rat liver, it underwent little biotransformation and was poorly transported (Tmax congruent with 0.5 micromol/min/kg) as compared with taurocholate. 5alpha-Cyprinol, its bile alcohol moiety, was oxidized to its corresponding C27 bile acid and to allocholic acid (the latter was then conjugated with taurine); these metabolites were efficiently transported. 5alpha-Cyprinol sulfate inhibited taurocholate uptake in COS-7 cells transfected with rat asbt, the apical bile salt transporter of the ileal enterocyte. 5alpha-Cyprinol had limited aqueous solubility (0.3 mM) and was poorly absorbed from the perfused rat jejunum or ileum. Sampling of carp intestinal content indicated that 5alpha-cyprinol sulfate was present at micellar concentrations, and that it did not undergo hydrolysis during intestinal transit. These studies indicate that 5alpha-cyprinol sulfate is an excellent digestive detergent and suggest that a micellar phase is present during digestion in cyprinid fish.     

Pathways of absorption of retinal and retinoic acid in the rat

The chemical and anatomical pathways of absorption of dietary retinal, retinoic acid, and retinol were examined in rats containing lymph, bile, and duodenal cannulae. The experiments were designed to maintain physiological conditions to the greatest possible extent. In each rat an uninterrupted flow of bile into the duodenum was maintained by connecting the duodenal cannula to the bile duct of a second rat. Labeled vitamin A compounds were introduced into the duodenum in very small amounts (7-14 micrograms) in the form of a bile-lipid mixture resembling normal intestinal contents. Under these conditions, most (70-80%) of the radioactivity recovered after the feeding of labeled retinol or retinal was found in the lymph, predominantly in saturated retinyl esters. In contrast, 92-95% of the radioactivity recovered after the feeding of labeled retinoic acid was found in the bile, and was contained in a mixture of polar metabolites, most of them more polar than free retinoic acid. Two-thirds of the small amount of radioactivity found in lymph after retinoic acid-(14)C feeding was in the form of free retinoic acid. The results indicate that under normal conditions the major pathway of retinal absorption involves its reduction to retinol, which is then esterified and transported via the lymphatics in a manner similar to that of dietary retinol. A small proportion of retinal is apparently normally oxidized, and is then transported via the portal vein and excreted in the bile in a manner similar to that of dietary retinoic acid. The relative importance, in quantitative terms, of these two pathways of retinal metabolism can vary, depending on the status of the animal.     

Synthesis of 19-hydroxy-[7-2H2]androstenedione for human metabolism studies

19-Hydroxyandrostenedione (19-OHA), highly labeled with deuterium at position 7, was synthesized from unlabeled androstenediol diacetate. The deuterium labels were introduced into the 7-keto compound with dichloroaluminum deuteride to obtain [7-2H2]androstenediol. The labeled androstenediol diacetate was converted to the labeled 19-OHA by a five-step sequence without appreciable loss of deuterium. The labeled 19-OHA is useful as an internal standard for gas chromatography-mass spectroscopy analysis of the endogenous levels and as a tracer for in vivo metabolic studies.     

Incorporation of the 1-pro-R and the 1-pro-S hydrogen atoms of ethanol into steroids and phosphatidylcholines in vivo.

The transfer of deuterium from chiral 1-monodeuteroethanols to various metabolites formed in the liver was studied in order to investigate the coupling of metabolic reductions to the alcohol dehydrogenase and the aldehyde dehydrogenase reactions. The ethanols were administered to female bile fistula rats for 10 h. The hydrogen at C-2 in the glycerol moiety of newly formed phosphatidylcholine molecules in bile, liver and plasma was derived to 22-25% from the 1-pro-R position and to 5-6% from the 1-pro-S position in the ethanol. sn-Glycerol 3-phosphate isolated from liver had a lower deuterium content at C-2. The ratio between the contributions from the two positions in ethanol to C-2 of free sn-glycerol 3-phosphate was the same as in the phosphatidylcholines. This indicates that the higher degree of labelling of this position in phosphatidylcholines is not due to a specific coupling between alcohol dehydrogenase and the formation of a phosphatidylcholine precursor. Cholesterol and chenodeoxycholic acid in bile became increasingly labelled, and the ratio between the incorporations from the 1-pro-S and the 1-pro-R positions of ethanol was about 0.37 in cholesterol and 0.46 in chenodeoxycholic acid. Thus, these NADPH-dependent reactions utilized hydrogen from the 1-pro-S position to a larger extent than NADH-dependent reactions.     

Metabolism of coenzyme Q10: biliary and urinary excretion study in guinea pigs.

Biliary and urinary metabolites were examined after intravenous administration of 14C-coenzyme Q10 (14C-CoQ) to guinea pigs. Cumulative recovery of administered radioactivity for up to 8 hours by bile drainage was 4.8%. The greater part of radioactivity was detected in conjugate form. After hydrolyzing with beta-glucuronidase, aglycone fragments were subjected to methylation and reductive acetylation. The main metabolite was demonstrated to be Q acid-1 1,4-hydroquinone diacetate methyl ester (M-1) on HPLC. Then, the main metabolite was assumed to be glucuronide of 2,3-dimethoxy-5-methyl-6-(3'-methyl-5'-carboxy-2'-pentenyl)-1, 4-benzohydroquinone [Q acid-I hydroquinone]. The cumulative urinary recovery of the administered radioactivity over 48 hours was 8.3%. The labeled samples were treated similarly to bile. The urinary metabolites of CoQ10 consisted of unconjugated and conjugated forms. Lyophilized urine was treated as a bile sample and analyzed. The two major metabolites were assigned to be M-1 and Q acid-II 1,4-hydroquinone diacetate methyl ester (M-2). Then, the two metabolites were assumed to be composed of Q acid-I and 2,3-dimethoxy-5-methyl-6-(3'-carboxypropyl)-1,4-benzoquinone (Q acid-II) in free and corresponding hydroquinone conjugate forms. To investigate the effect of exogenous labeled CoQ10 on unlabeled CoQ10 (endogenous) metabolites in urine, simultaneous quantitative determination was performed using deuterium labeled CoQ10 (CoQ10-d5). Urine collected over a 72-hour period after intravenous administration of CoQ10-d5 was processed similarly to that described above and two derivatized metabolites (M-1 and M-2) were quantified by gas chromatography-mass fragmentography with the multi-ion detection method. The analytical results showed that the addition of exogenous labeled CoQ10 did not influence the metabolism (or breakdown) of unlabeled (endogenous) CoQ10.     

Bile acid synthesis in cell culture

Confluent cultures of Hep G2 cells were found to synthesize chenodeoxycholic and cholic acids continually. Chenodeoxycholic acid was synthesized at the rate of 58 +/- 8.6 micrograms/96 h, a rate more than 7-fold greater than that for cholic acid. Addition of 5 beta-cholestane-3 alpha, 7 alpha, 12 alpha-triol but not the -3 alpha, 7 alpha-diol was followed by an increase in cholic acid synthesis, thus indicating a relatively low 12 alpha-hydroxylase activity. Endogenous synthesis of monohydroxy bile acid ester sulfates was found, with maximum rates of 135 and 74 micrograms/96 h for lithocholic and 3 alpha-hydroxy-5-cholenoic acids, respectively. Incubation of Hep G2 cells in medium containing 25% D2O permitted a comparison of the precursor/product relationship of cholesterol with 3 beta-hydroxy-5-cholenoic acid. The pattern of incorporation of deuterium was in accordance with that expected, thus allowing the conclusion that this monohydroxy bile acid is derived from cholesterol and should be considered together with chenodeoxycholic and cholic acids as a primary bile acid.     

Exchange of methyl hydrogens in ethanol during incorporation in bile acids in vivo

[2,2,2-2H]Ethanol was administered continuously to bile fistula rats for 72 h, with or without (--)-hydroxycitrate. The deuterium labelling of biliary bile acids was determined by GC-MS and 13C NMR. Difference spectra between 2H,1H- and 1H-decoupled 13C NMR spectra showed the presence of partly deuterated methyl and methylene groups in methyl cholate, indicating exchange of deuterium in [2,2,2-2H]ethanol for protium prior to or during incorporation of acetate into the bile acid. The extent of exchange was 20--30% as calculated from the isotopic composition of a fragment ion containing one methyl and one methylene group derived from C-2 of acetate. The exchange was unaffected by (--)-hydroxycitrate, indicating that it was not due to reversible incorporation of deuterated acetate into citrate. About 60% of the acetyl-CoA serving as precursor of cholic and chenodeoxycholic acids were derived from ethanol. This value was not changed by administration of (--)-hydroxycitrate. The half-life time of cholesterol molecules acting as precursors of both bile acids was about 50 h in the presence of (--)-hydroxycitrate, which is about the same as previously found in the absence of the inhibitor.     

PBAN regulation of pheromone biosynthesis in female tobacco hornworm moths,Manduca sexta (L.)

Manduca sexta females that were decapitated produced no pheromone during the scotophase following decapitation, indicating that they were free of pheromone biosynthesis activating neuropeptide (PBAN). When deuterated hexadecanoic or (Z)-11-hexadecenoic acid was applied to the sex pheromone glands of decapitated or intact females of the same age, and allowed to incubate in vivo for 24 h, deuterium labeled Δ-11- and Δ-10, 12-unsaturated 16-carbon fatty acids were produced in both types of females. Injection of PBAN into intact or decapitated females 23 h after application of labeled acids had no effect on the production of unsaturated labeled fatty acids. However, deuterium labeled aldehydes were produced only in females that were injected with PBAN. Therefore, in this species, PBAN activates the process by which fatty acyl precursors in the pheromone gland are converted into the pheromonal aldehydes. © 1995 Wiley-Liss, Inc.

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

     

Metabolism of intravenously administered 7 alpha-hydroxycholesterol-3 beta-stearate in the hamster.

In order to investigate the metabolic fate of serum esterified 7 alpha-hydroxycholesterol, [4-14C]7 alpha-hydroxycholesterol-3 beta-stearate was synthesized from labeled cholesterol and administered to bile fistula hamsters intravenously. Bile samples were collected at every 20 min for 7 h. Radioactivity was detected in bile 40 min after the beginning of the infusion of the labeled compound and 56.5 +/- 5.7% (48.7-66.0%) of the administered radioactivity was recovered in bile during 7 h. The liver contained appreciable radioactivity (19.5 +/- 7.6% of the administered dose) at the time of sacrifice. Only a trace amount of radioactivity was detected in urine and blood. Cumulative recovery of the radioactivity was 76.3 +/- 8.6% (63.3-90.4%). Major radioactive metabolites in the bile samples were identified to be taurine- and glycine-conjugated cholic acid and chenodeoxycholic acid by radioactive thin-layer chromatographic analysis of the bile samples before and after enzymatic hydrolysis and 3 alpha-hydroxysteroid dehydrogenase treatment. The conversion was nearly complete and we could not detect neutral metabolites, such as the mother compound, free 7 alpha-hydroxycholesterol and bile alcohols, as well as glucuronidated or sulfated bile acids. It is concluded that serum esterified 7 alpha-hydroxycholesterol could be effectively taken up by the liver, hydrolyzed by cholesterol esterase and metabolized via the normal biosynthetic pathway to taurine- or glycine-conjugated primary bile acids to be excreted into bile.