Cyp2c70 is responsible for the species difference in bile acid metabolism between mice and humans.

Bile acids are synthesized from cholesterol in the liver and subjected to multiple metabolic biotransformations in hepatocytes, including oxidation by cytochromes P450 (CYPs) and conjugation with taurine, glycine, glucuronic acid, and sulfate. Mice and rats can hydroxylate chenodeoxycholic acid (CDCA) at the 6ß-position to form α-muricholic acid (MCA) and ursodeoxycholic acid (UDCA) to form ß-MCA. However, MCA is not formed in humans to any appreciable degree and the mechanism for this species difference is not known. Comparison of several Cyp-null mouse lines revealed that α-MCA and ß-MCA were not detected in the liver samples from Cyp2c-cluster null (Cyp2c-null) mice. Global bile acid analysis further revealed the absence of MCAs and their conjugated derivatives, and high concentrations of CDCA and UDCA in Cyp2c-null mouse cecum and feces. Analysis of recombinant CYPs revealed that α-MCA and ß-MCA were produced by oxidation of CDCA and UDCA by Cyp2c70, respectively. CYP2C9-humanized mice have similar bile acid metabolites as the Cyp2c-null mice, indicating that human CYP2C9 does not oxidize CDCA and UDCA, thus explaining the species differences in production of MCA. Because humans do not produce MCA, they lack tauro-ß-MCA, a farnesoid X receptor antagonist in mouse that modulates obesity, insulin resistance, and hepatosteatosis.

Structure and functional characterization of a bile acid 7α dehydratase BaiE in secondary bile acid synthesis.

Conversion of the primary bile acids cholic acid (CA) and chenodeoxycholic acid (CDCA) to the secondary bile acids deoxycholic acid (DCA) and lithocholic acid (LCA) is performed by a few species of intestinal bacteria in the genus Clostridium through a multistep biochemical pathway that removes a 7α-hydroxyl group. The rate-determining enzyme in this pathway is bile acid 7α-dehydratase (baiE). In this study, crystal structures of apo-BaiE and its putative product-bound [3-oxo-Δ(4,6) -lithocholyl-Coenzyme A (CoA)] complex are reported. BaiE is a trimer with a twisted α + ß barrel fold with similarity to the Nuclear Transport Factor 2 (NTF2) superfamily. Tyr30, Asp35, and His83 form a catalytic triad that is conserved across this family. Site-directed mutagenesis of BaiE from Clostridium scindens VPI 12708 confirm that these residues are essential for catalysis and also the importance of other conserved residues, Tyr54 and Arg146, which are involved in substrate binding and affect catalytic turnover. Steady-state kinetic studies reveal that the BaiE homologs are able to turn over 3-oxo-Δ(4) -bile acid and CoA-conjugated 3-oxo-Δ(4) -bile acid substrates with comparable efficiency questioning the role of CoA-conjugation in the bile acid metabolism pathway.

New insights into bile acid malabsorption.

Bile acid malabsorption occurs when there is impaired absorption of bile acids in the terminal ileum, so interrupting the normal enterohepatic circulation. The excess bile acids in the colon cause diarrhea, and treatment with bile acid sequestrants is beneficial. The condition can be diagnosed with difficulty by measuring fecal bile acids, or more easily by retention of selenohomocholyltaurine (SeHCAT), where this is available. Chronic diarrhea caused by primary bile acid diarrhea appears to be common, but is under-recognized where SeHCAT testing is not performed. Measuring excessive bile acid synthesis with 7α-hydroxy-4-cholesten-3-one may be an alternative means of diagnosis. It appears that there is no absorption defect in primary bile acid diarrhea but, instead, an overproduction of bile acids. Fibroblast growth factor 19 (FGF19) inhibits hepatic bile acid synthesis. Defective production of FGF19 from the ileum may be the cause of primary bile acid diarrhea.

Abolished synthesis of cholic acid reduces atherosclerotic development in apolipoprotein E knockout mice.

To investigate the effects of abolished cholic acid (CA) synthesis in the ApoE knockout model [apolipoprotein E (apoE) KO],a double-knockout (DKO) mouse model was created by crossbreeding Cyp8b1 knockout mice (Cyp8b1 KO), unable to synthesize the primary bile acid CA, with apoE KO mice. After 5 months of cholesterol feeding, the development of atherosclerotic plaques in the proximal aorta was 50% less in the DKO mice compared with the apoE KO mice. This effect was associated with reduced intestinal cholesterol absorption, decreased levels of apoB-containing lipoproteins in the plasma, enhanced bile acid synthesis, reduced hepatic cholesteryl esters, and decreased hepatic activity of ACAT2. The upregulation of Cyp7a1 in DKO mice seemed primarily caused by reduced expression of the intestinal peptide FGF15. Treatment of DKO mice with the farnesoid X receptor (FXR) agonist GW4064 did not alter the intestinal cholesterol absorption, suggesting that the action of CA in this process is confined mainly to formation of intraluminal micelles and less to its ability to activate the nuclear receptor FXR. Inhibition of CA synthesis may offer a therapeutic strategy for the treatment of hyperlipidemic conditions that lead to atherosclerosis.

Metabolism of Non-Enzymatically Derived Oxysterols: Clues from sterol metabolic disorders.

Cholestane-3ß,5α,6ß-triol (3ß,5α,6ß-triol) is formed from cholestan-5,6-epoxide (5,6-EC) in a reaction catalysed by cholesterol epoxide hydrolase, following formation of 5,6-EC through free radical oxidation of cholesterol. 7-Oxocholesterol (7-OC) and 7ß-hydroxycholesterol (7ß-HC) can also be formed by free radical oxidation of cholesterol. Here we investigate how 3ß,5α,6ß-triol, 7-OC and 7ß-HC are metabolised to bile acids. We show, by monitoring oxysterol metabolites in plasma samples rich in 3ß,5α,6ß-triol, 7-OC and 7ß-HC, that these three oxysterols fall into novel branches of the acidic pathway of bile acid biosynthesis becoming (25R)26-hydroxylated then carboxylated, 24-hydroxylated and side-chain shortened to give the final products 3ß,5α,6ß-trihydroxycholanoic, 3ß-hydroxy-7-oxochol-5-enoic and 3ß,7ß-dihydroxychol-5-enoic acids, respectively. The intermediates in these pathways may be causative of some phenotypical features of, and/or have diagnostic value for, the lysosomal storage diseases, Niemann Pick types C and B and lysosomal acid lipase deficiency. Free radical derived oxysterols are metabolised in human to unusual bile acids via novel branches of the acidic pathway, intermediates in these pathways are observed in plasma.

Loss of Enzymes in the Bile Acid Synthesis Pathway Explains Differences in Bile Composition among Mammals.

Bile acids are important for absorbing nutrients. Most mammals produce cholic and chenodeoxycholic bile acids. Here, we investigated genes in the bile acid synthesis pathway in four mammals that deviate from the usual mammalian bile composition. First, we show that naked-mole rats, elephants, and manatees repeatedly inactivated CYP8B1, an enzyme uniquely required for cholic acid synthesis, which explains the absence of cholic acid in these species. Second, no gene-inactivating mutations were found in any pathway gene in the rhinoceros, a species that lacks bile acids, indicating an evolutionarily recent change in its bile composition. Third, elephants and/or manatees that also lack bile acids altogether have lost additional nonessential enzymes (SLC27A5, ACOX2). Apart from uncovering genomic differences explaining deviations in bile composition, our analysis of bile acid enzymes in bile acid-lacking species suggests that essentiality prevents gene loss, while loss of pleiotropic genes is permitted if their other functions are compensated by functionally related proteins.

Cerebrotendinous xanthomatosis: a defect in mitochondrial 26-hydroxylation required for normal biosynthesis of cholic acid.

Oxidation of side chain of 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol was studied in a patient with cerebrotendinous xanthomatosis (CTX) and in control subjects, using various subcellular fractions of liver homogenate and a method based on isotope dilution-mass spectrometry. In the control, 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol was converted into 5 beta-cholestane-3 alpha,7 alpha,12 alpha,26-tetrol and 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholestanoic acid by the mitochondrial fraction, and into 5 beta-cholestane-3 alpha,7 alpha,12 alpha,-25-tetrol by the microsomal fraction. In the CTX patient, liver mitochondria were completely devoid of 26-hydroxylase activity. The same mitochondrial fraction catalyzed 25-hydroxylation of vitamin D3. The microsomal fraction of liver of the subject with CTX contained more than 50-fold the normal amount of 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol. The basic metabolid defect in CTX appears to be a lack of the mitochondrial 26-hydroxylase. The excretion in the bile of 5 beta-cholestane-3 alpha,7 alpha,12 alpha,25-tetrol and 5 beta-cholestane-3 alpha,7 alpha,12 alpha,24 alpha,25-pentol observed in CTX patients may be secondary to the accumulation of the major substrate for the 26-hydroxylase, i. e., 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol, and exposure of this substrate to the normally less active microsomal 25-and 24-hydroxylases. It is concluded that the major pathway in the biosynthesis of cholic acid in human liver involves a mitochondrial C27-steroid 26-hydroxylation.

Bile alcohol metabolism in man. Conversion of 5beta-cholestane-3alpha, 7alpha,12alpha, 25-tetrol to cholic acid.

To study the role of C25-HYDROXY BILE ALCOHOLS AS PRECURSORS OF CHOlic acid, [G-3-H]5beta-cholestane-3alpha,7alpha12alpha,25-tetrol was administered intravenously to two subjects with cerebrotendinous xanthomatosis (CTX) and two normal individuals. One day after pulse labeling, radioactivity was present in the cholic acid isolated from the bile and feces of the subjects with CTX and the bile of the normal individuals. In the two normal subjects, the sp act decay curves of [G-3-H]-cholic acid were exponential, and no traces of [G-3-H]-5beta-cholestane-3alpha,7alpha,12alpha,25-tetrol were detected. In contrast, appreciable quantities of labeled 5beta-cholestane-3alpha,-7aopha,12alpha,25-tetrol were present in the bile and feces of the CTX subjects. The sp act vs. time curves of fecal [G-3-H]5beta-cholestane-3alpha,7alpha,12alpha,25-tetrol and [G-3-H]-cholic acid showed a precursor-product relationship. Although these results suggest that 5beta-cholestane-3alpha,7alpha,12alpha,25-tetrol may be a precursor of cholic acid in man, the possibility that C26-hydroxy intermediates represent the normal pathway can not be excluded.

Cholic acid biosynthesis: the enzymatic defect in cerebrotendinous xanthomatosis.

Cholic acid biosynthesis is defective in individuals with cerebrotendinous xanthomatosis (CTX) and is associated with the excretion of 5beta-cholestane-3alpha,7alpha, 12alpha,25-tetrol, an intermediate in the 25-hydroxylation pathway of cholic acid in CTX. To define the enzymatic defect in CTX, two suspected precursors of cholic acid, namely 5beta-[7beta-(3)H]cholestane-3alpha,7alpha, 12alpha-triol and 5beta-[24-(14)C]cholestane-3alpha,7alpha, 12alpha,24S,25-pentol were examined by both in vivo and in vitro experiments. A third precursor, 5beta-[7beta-(3)H]-cholestane-3alpha,7alpha, 12alpha,25-tetrol, was compared with them in vitro. In the in vivo experiments, each one of the labeled precursors was administered intravenously to two CTX and two control subjects. In the controls, 5beta-[7beta-(3)H]cholestane-3alpha,7alpha, 12alpha-triol as well as 5beta-[24-(14)C]-cholestane-3alpha,7alpha, 12alpha,24S,25-pentol were rapidly converted to labeled cholic acid. Maximum specific activity values were reached within 1 d after pulse labeling, followed by exponential decay of the cholic acid specific activity curves. In contrast, these two precursors differed widely when administered to two CTX patients. While 5beta-[24-(14)C]cholestane-3alpha,7alpha, 12alpha,24S,25-pentol was rapidly converted to [24-(14)C]cholic acid and yielded identical decay curves with those obtained in the control subjects, maximum specific activity values in [7beta-(3)H]cholic acid were much lower and peaked only on the second day after the injection of 5beta-[7beta-(3)H]cholestane-3alpha,7alpha, 12alpha-triol. Furthermore, an appreciable amount of (3)H label was present in the 5beta-cholestane-3alpha,7alpha, 12alpha,25-tetrol isolated from the bile of the subjects with CTX. In the in vitro experiments, three enzymes on the 25-hydroxylation pathway of cholic acid were examined in both control and CTX subjects. The rate of the 25-hydroxylation of 5beta-cholestane-3alpha,7alpha, 12alpha-triol in CTX patients was comparable to that in the controls. Similarly, the transformation of 5beta-cholestane-3alpha,7alpha, 12alpha,24S,25-pentol to cholic acid, catalyzed by soluble enzymes, proceeded at approximately equal rates in CTX and in control individuals. On the other hand, the rate of 5beta-cholestane-3alpha,7alpha, 12alpha,24S,25-pentol formation was about four times greater in the control subjects than in the CTX patients.The results of the in vivo as well as the in vitro experiments suggest that the site of the enzymatic defect in CTX is at the 24S-hydroxylation of 5beta-cholestane-3alpha,7alpha, 12alpha,25-tetrol. The relative deficiency of this hydroxylase in CTX patients, accompanied by the accumulation of its substrate in bile and feces, probably accounts for the subnormal production of bile acids in CTX patients.

Defective peroxisomal cleavage of the C27-steroid side chain in the cerebro-hepato-renal syndrome of Zellweger.

Based on in vitro work with rat liver, we recently suggested that the peroxisomal fraction is most important for the oxidation of 3 alpha, 7 alpha, 12 alpha-trihydroxy-5 beta-cholestanoic acid (THCA) into cholic acid. The cerebro-hepato-renal syndrome of Zellweger is a fatal recessive autosomal disorder, the most characteristic histological feature of which is a virtual absence of peroxisomes in liver and kidneys. This disease offers a unique opportunity to evaluate the relative importance of peroxisomes in bile acid biosynthesis. A child with Zellweger syndrome was studied in the present work. In accordance with previous work, there was a considerable accumulation of THCA, 3 alpha, 7 alpha, 12 alpha, 24-tetrahydroxy-5 beta-cholestanoic acid (24-OH-THCA), 3 alpha, 7 alpha, 12 alpha-trihydroxy-27-carboxymethyl-5 beta-cholestan-26-oic acid (C29-dicarboxylic acid), and 3 alpha, 7 alpha-dihydroxy-5 beta-cholestanoic acid in serum. In addition, a tetrahydroxylated 5 beta-cholestanoic acid with all the hydroxyl groups in the steroid nucleus was found. 3H-Labeled 5 beta-cholestane-3 alpha, 7 alpha, 12 alpha-triol was administered intravenously together with 14C-labeled cholic acid. There was a rapid incorporation of 3H in THCA and a slow incorporation into cholic acid. The specific radioactivity of 3H in THCA was about one magnitude higher than that in cholic acid. The conversion was evaluated by following the increasing ratio between 3H and 14C in biliary cholic acid. The rate of incorporation of 3H in cholic acid was considerably less than previously reported in experiments with healthy subjects, and the maximal conversion of the triol into cholic acid was only 15-20%. About the same rate of conversion was found after oral administration of 3H-THCA. Both in the experiment with 3H-5 beta-cholestane-3 alpha, 7 alpha, 12 alpha-triol and with 3H-THCA, there was an efficient incorporation of 3H in the above unidentified tetrahydroxylated 5 beta-cholestanoic acid. There was only slow incorporation of radioactivity into 24-OH-THCA and into the C29-dicarboxylic acid. From the specific activity decay curve of 14C in cholic acid obtained after intravenous injection of 14C-cholic acid, the pool size of cholic acid was calculated to be 24 mg/m2 and the daily production rate to 9 mg/m2 per d. This corresponds to a reduction of approximately 85 and 90%, respectively, when compared with normal infants. It is concluded that liver peroxisomes are essential in the normal conversion of THCA to cholic acid. In the Zellweger syndrome this conversion is defective and as a consequence the accumulated THCA is either excreted as such or transformed into other metabolites by hydroxylation or side chain elongation. The accumulation of THCA, as well as the similar rate of conversion of 5 beta-cholestane-3 alpha,7 alpha.12 alpha-triol and THCA into cholic acid, support the contention that the 26-hydroxylase pathway with intermediate formation of THCA is the most important pathway for formation of cholic acid in man.

In vivo and vitro studies on formation of bile acids in patients with Zellweger syndrome. Evidence that peroxisomes are of importance in the normal biosynthesis of both cholic and chenodeoxycholic acid.

The last step in bile acid formation involves conversion of 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-cholestanoic acid (THCA) into cholic acid and 3 alpha,7 alpha-dihydroxy-5 beta-cholestanoic acid (DHCA) into chenodeoxycholic acid. The peroxisomal fraction of rat and human liver has the highest capacity to catalyze these reactions. Infants with Zellweger syndrome lack liver peroxisomes, and accumulate 5 beta-cholestanoic acids in bile and serum. We recently showed that such an infant had reduced capacity to convert a cholic acid precursor, 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol into cholic acid. 7 alpha-Hydroxy-4-cholesten-3-one is a common precursor for both cholic acid and chenodeoxycholic acid. Intravenous administration of [3H]7 alpha-hydroxy-4-cholesten-3-one to an infant with Zellweger syndrome led to a rapid incorporation of 3H into biliary THCA but only 10% of 3H was incorporated into cholic acid after 48 h. The incorporation of 3H into DHCA was only 25% of that into THCA and the incorporation into chenodeoxycholic acid approximately 50% of that in cholic acid. The conversion of intravenously administered [3H]THCA into cholic acid in another infant with Zellweger syndrome was only 7%. There was a slow conversion of THCA into 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-C29-dicarboxylic acid. The pool size of both cholic- and chenodeoxycholic acid was markedly reduced. Preparations of liver from two patients with Zellweger syndrome had no capacity to catalyze conversion of THCA into cholic acid. There was, however, a small conversion of DHCA into chenodeoxycholic acid and into THCA. It is concluded that liver peroxisomes are important both for the conversion of THCA into cholic acid and DHCA into chenodeoxycholic acid.

Biosynthesis of bile acids in cerebrotendinous xanthomatosis. Relationship of bile acid pool sizes and synthesis rates to hydroxylations at C-12, C-25, and C-26.

To examine the defect in side-chain oxidation during the formation of bile acids in cerebrotendinous xanthomatosis, we measured in vitro hepatic microsomal hydroxylations at C-12 and C-25 and mitochondrial hydroxylation at C-26 and related them to the pool size and synthesis rates of cholic acid and chenodeoxycholic acid as determined by the isotope dilution technique. Hepatic microsomes and mitochondria were prepared from seven subjects with cerebrotendinous xanthomatosis and five controls. Primary bile acid synthesis was markedly reduced in cerebrotendinous xanthomatosis as follows: cholic acid, 133 +/- 30 vs. 260 +/- 60 mg/d in controls; and chenodeoxycholic acid, 22 +/- 10 vs. 150 +/- 30 mg/d in controls. As postulated for chenodeoxycholic acid synthesis, mitochondrial 26-hydroxylation of 5 beta-cholestane-3 alpha, 7 alpha-diol was present in all specimens and was 30-fold more active than the corresponding microsomal 25-hydroxylation. However, mean mitochondrial 26-hydroxylation of 5 beta-cholestane-3 alpha,7 alpha-diol was less active in cerebrotendinous xanthomatosis than in controls: 59 +/- 17 compared with 126 +/- 21 pmol/mg protein per min. As for cholic acid synthesis, microsomal 25-hydroxylation of 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol was substantially higher in cerebrotendinous xanthomatosis and control preparations (620 +/- 103 and 515 +/- 64 pmol/mg protein per min, respectively) than the corresponding control mitochondrial 26-hydroxylation of the same substrate (165 +/- 25 pmol/mg protein per min). Moreover in cerebrotendinous xanthomatosis, mitochondrial 5 beta-cholestane-3 alpha,7 alpha,12 alpha-triol-26-hydroxylase activity was one-seventh as great as in controls. Hepatic microsomal 12 alpha-hydroxylation, which may be rate-controlling for the cholic acid pathway, was three times more active in cerebrotendinous xanthomatosis than in controls: 1,600 vs. 500 pmol/mg protein per min. These results demonstrate severely depressed primary bile acid synthesis in cerebrotendinous xanthomatosis with a reduction in chenodeoxycholic acid formation and pool size disproportionately greater than that for cholic acid. The deficiency of chenodeoxycholic acid can be accounted for by hyperactive microsomal 12 alpha-hydroxylation that diverts precursors into the cholic acid pathway combined with decreased side-chain oxidation (mitochondrial 26-hydroxylation). However, side-chain oxidation in cholic acid biosynthesis may be initiated via microsomal 25-hydroxylation of 5beta-cholestane-3alpha,7alpha,12alpha-triol was substantially lower in control and cerebrotendinous xanthomatosis liver. Thus, separate mechanisms may exist for the cleavage of the cholesterol side chain in cholic acid and chenodeoxycholic acid biosynthesis.

Effects of cholecystectomy on the kinetics of primary and secondary bile acids.

Removal of the gallbladder is thought to increase formation and pool size of secondary bile acids, mainly deoxycholic acid (DCA), by increased exposure of primary bile acids (cholic acid [CA], chenodeoxycholic acid [CDCA]) to bacterial dehydroxylation in the intestine. We have tested this hypothesis by simultaneous determination of pool size and turnover of DCA, CA, and CDCA in nine women before and at various intervals after removal of a functioning gallbladder. An isotope dilution technique using marker bile acids labeled with stable isotopes (2H4-DCA, 13C-CA, 13C-CDCA) was used. After cholecystectomy, concentration and output of bile acids relative to bilirubin increased (P less than 0.02) in fasting duodenal bile and cholesterol saturation decreased by 27% (P less than 0.05) consistent with enhanced enterohepatic cycling of bile acids. Three months after removal of the gallbladder bile acid kinetics were in a new steady state: pool size and turnover of CDCA were unchanged. Synthesis of CA, the precursor of DCA, was diminished by 37% (P = 0.05), probably resulting from feedback inhibition by continuous transhepatic flux of bile acids. The fraction of CA transferred after 7 alpha-dehydroxylation to the DCA pool increased from 46 +/- 16 to 66 +/- 32% (P less than 0.05). However, this enhanced transfer did not lead to increased input or size of the DCA pool, because synthesis of the precursor CA had decreased.

The metabolism of 3alpha, 7alpha, 12alpha-trihydorxy-5beta-cholestan-26-oic acid in two siblings with cholestasis due to intrahepatic bile duct anomalies. An apparent inborn error of cholic acid synthesis.

Studies were carried out in a family in which two children with cholestasis due to intrahepatic bile duct anomalies were shown to have increased amounts of the cholic acid precursor, 3alpha, 7alpha, 12alpha-trihydorxy-5beta-cholestan-26-oic acid (THCA). The metabolism of THCA was studied in one of these patients after an intravenous injection of (3H)THCA, and the cause of the increased amounts of THCA in this condition was found to be due to a metabolic defect in the conversion of this compound into cholic acid. A small amount of (3H)cholic acid was also identified after (3H)THCA administration, confirming that this metabolic defect was incomplete. Varanic acid (3alpha, 7alpha, 12alpha, 24xi-tetrahydorxy-5beta-cholestan-26-oic acid), a metabolite of THCA, could not be identified in either of these patients. By assuming that this compound would be conjugated and excreted if the metabolic block occurred after the formation of varanic acid, the defect in these patients appears to be due to a deficiency of a 24-hydroxylating enzyme system required to convert THCA into varanic acid. This condition appears to be transmitted in an autosomal recessive fashion, because the two affected patients were of opposite sex, and neither a normal sibling nor the two parents have increased amount of THCA in their bile.

Biosynthesis of bile acids in a variety of marine bacterial taxa.

Several marine bacterial strains, which were isolated from seawater off the island Dokdo, Korea, were screened to find new bioactive compounds such as antibiotics. Among them, Donghaeana dokdonensis strain DSW-6 was found to produce antibacterial agents, and the agents were then purified and analyzed by LC-MS/MS and 1D- and 2D-NMR spectrometries. The bioactive compounds were successfully identified as cholic acid and glycine-conjugated glycocholic acid, the 7alpha-dehydroxylated derivatives (deoxycholic acid and glycodeoxycholic acid) of which were also detected in relatively small amounts. Other masine isolates, taxonomically different from DSW-6, were also able to produce the compounds in a quite different production ratio from DSW-6. As far as we are aware of, these bile acids are produced by specific members of the genus Streptomyces and Myroides, and thought to be general secondary metabolites produced by a variety of bacterial taxa that are widely distributed in the sea.

[Action of the microbial flora of the digestive tract on the biosynthesis of cholic acid in the rat (author's transl)]. / Action de la flore microbienne du tractus digestif sur la biosynthèse de l'acide cholique chez le rat.

Axenic and holoxenic (conventional) rats were fed a diet containing trace amounts of [2,4-3H]cholic and [24-14C]chemodeoxycholic acids. In the feces of both groups of rats, the percentage of labelled bile acids which were 3H-labelled was slightly different. In the experimental conditions used, the intestinal microflora only slightly modified the synthesis of 12alpha-hydroxylated bile acids.

Biosynthesis of 5 alpha- and 5 beta-cholanoic acid derivatives during metabolism of [1,1-2H]- and [2,2,2-2H]ethanol in the rat.

Female bile fistula rats were given [1,1-2H]ethanol in a single dose or [2,2,2-2H]ethanol repeatedly for 24 h and incorporation of deuterium into the following bile acids was determined: taurine conjugates of 3 alpha, 7 alpha, 12 alpha-trihydroxy-5(alpha and beta)-cholanoic, 3 alpha, 7 alpha-dihydroxy-5(alpha and beta)-cholanoic and 3 alpha, 6 beta, 7 alpha-trihydroxy-5 beta-cholanoic acids; sulphates of 3(alpha and beta), 7 alpha, 12 alpha-trihydroxy-5 alpha-cholanoic, and 3(alpha and beta), 7 alpha-dihydroxy-5 alpha-cholanoic acids. The kinetics of deuterium incorporation from [2,2,2-2H]ethanol was the same for all bile acids indicating that they were formed from a single pool of cholesterol. The labelling pattern of bile acids formed during metabolism of [1,1-2H]-ethanol indicated that the hydrogen at C-5 was labelled in all bile acids. Taken together with previous results this indicates that 3-oxo-4-cholenoic acid is not an intermediate in the formation of allo bile acids. The results support the view that formation of allo bile acids via a mitochondrial pathway is of little importance in the bile fistula rat.

Isocholic acid formation from 7 alpha,12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid with human liver enzyme.

The formation of isocholic acid from 7 alpha, 12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid by human liver preparations was examined in vitro. Liver preparations were incubated with 7 alpha, 12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid at pH 7.4 in a phosphate buffer containing NADPH or NADH. The products formed were analyzed by gas chromatography and gas chromatography/mass spectrometry. Results showed that 7 alpha,12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid was reduced mainly to isocholic acid and to cholic acid in a smaller amount in the presence of NADPH, while it was reduced only to cholic acid in the presence of NADH. The reducing enzyme participating in the formation of isocholic acid was localized largely in the cytosol and had more specificity to the unconjugated form as substrate than to the conjugated forms. 3-Keto bile acid analogues, 3-keto-5 beta-cholanoic and 7 alpha-hydroxy-3-keto-5 beta-cholanoic acids were not reduced to the corresponding iso-bile acids by the cytosol in the same conditions used in the isocholic acid formation and the activity of the enzyme catalyzing the reduction of 7 alpha,12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid to isocholic acid was not inhibited by the addition of 3-keto-5 beta-cholanoic acid or 7 alpha-hydroxy-3-keto-5 beta-cholanoic acid to the reaction mixture. Furthermore, on column chromatography of Affi-Gel Blue, the peak of the enzyme catalyzing the reduction of 7 alpha,12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid to isocholic acid was clearly distinguished from that of the enzyme catalyzing the reduction of 3-keto-5 beta-cholanoic acid to isolithocholic acid and that of alcohol dehydrogenase. These results indicate that this enzyme catalyzing the reduction of 7 alpha,12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid to isocholic acid is different from the enzyme(s) catalyzing the reduction 3-keto-5 beta-cholanoic and 7 alpha-hydroxy-3-keto-5 beta-cholanoic acids to the corresponding iso-bile acids and from alcohol dehydrogenase, and has a stereospecific character for 7 alpha,12 alpha-dihydroxy-3-keto-5 beta-cholanoic acid.

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.

Formation of cholic acid and chenodeoxycholic acid from 7 alpha-hydroxycholesterol and 27-hydroxycholesterol by primary cultures of human hepatocytes.

It has been suggested that chenodeoxycholic acid is preferentially formed by the alternative or 'acidic' pathway of bile acid biosynthesis starting with 27-hydroxylation of cholesterol, while cholic acid is derived from 7 alpha-hydroxycholesterol which initiates the 'neutral' pathway. We have studied bile acid formation from each of these precursors using human hepatocytes cultured in a novel sandwich collagen configuration. Culture supernatants were analyzed using capillary gas chromatography and gas chromatography-mass spectrometry. 27-Hydroxycholesterol and 7 alpha-hydroxycholesterol were both found to be efficiently converted to cholic acid as well as chenodeoxycholic acid. Analysis of acidic intermediates after addition of 7 alpha-hydroxycholesterol to the cultures revealed a significant increase of side-chain oxygenated C24- and C27-steroids with a 3-oxo-7 alpha-hydroxy-delta 4-ring structure. These data indicate that (i) the 'neutral' pathway is connected to the 'acidic' pathway by side-chain oxidation of C27-steroids with a 3-oxo-7 alpha-hydroxy-delta 4-ring structure and that (ii) the relative formation of cholic acid and chenodeoxycholic acid is regulated by metabolic events distal to the initial hydroxylation at either position 7 or position 27 of the cholesterol molecule.