R Lester

Lithocholate glucuronide is a cholestatic agent.

Lithocholic acid and its taurine, glycine, and sulfate derivatives are potent cholestatic agents. Lithocholate glucuronide is present in the plasma and urine of patients with cholestatic syndromes, but little is known of its metabolism, excretion, and cholestatic potential. [3 beta-3H]lithocholate 3-O-beta-D-glucuronide was synthesized, and chemical and radiochemical purity were established. The aqueous solubility of lithocholate glucuronide was determined and found to be greater than that of lithocholic acid or several of its derivatives. In the range of concentrations examined, calcium ions precipitated lithocholate glucuronide stoichiometrically. The material was administered to rats prepared with an external biliary fistula. When 17-25 micrograms quantities were administered, 89.1 +/- 4.5% (mean +/- SEM) of the radiolabel was secreted in bile within the first 20 h after administration, the major fraction being secreted in less than 20 min. Four-fifths of the radiolabeled material in bile was the administered unaltered parent compound, while a minor fraction consisted of a more polar derivative(s). We showed that increasing biliary concentrations of more polar derivatives were observed with milligram doses of [3H]lithocholate glucuronide, and with time after the administration of these loading doses. Milligram doses of [3H]lithocholate glucuronide resulted in partial or complete cholestasis. When induced cholestasis was partial, secretion in bile remained the primary excretory route (82.5-105.6% recovery in bile), while, when complete cholestasis was induced, wide tissue distribution of radiolabel was observed. Cholestasis developed rapidly during infusion of [3H]lithocholate glucuronide. Bile flow was diminished within 10-20 min of the start of an infusion of 0.05 mumol, 100 g-1 body weight, minute-1, administered concomitantly with an equimolar infusion of taurocholate. The results establish that lithocholate glucuronide exerts cholestatic effects comparable to those exerted by unconjugated lithocholic acid.

Glucuronidation of 6 alpha-hydroxy bile acids by human liver microsomes.

The glucuronidation of 6-hydroxylated bile acids by human liver microsomes has been studied in vitro; for comparison, several major bile acids lacking a 6-hydroxyl group were also investigated. Glucuronidation rates for 6 alpha-hydroxylated bile acids were 10-20 times higher than those of substrates lacking a hydroxyl group in position 6. The highest rates measured were for hyodeoxy- and hyocholic acids, and kinetic analyses were carried out using these substrates. Rigorous product identification by high-field proton nuclear magnetic resonance and by electron impact mass spectrometry of methyl ester/peracetate derivatives revealed that 6-O-beta-D-glucuronides were the exclusive products formed in these enzymatic reactions. These results, together with literature data, indicate that 6 alpha-hydroxylation followed by 6-O-glucuronidation constitutes an alternative route of excretion of toxic hydrophobic bile acids.

Rapid stimulation of Na+,K+-ATPase by glucagon, epinephrine, vasopressin and cAMP in perfused rat liver

Hormones which promote glucose production by the liver have a pronounced effect on ion distribution in this organ. The redistribution of ions is prompt and involves several ions. Glucagon [ 1,2], epinephrine [ 1,2], norepinephrine [ 11, phenyl epinephrine [3,4] and vasopressin [ 51 affect K’ movement across the plasma membrane. A similar response is evoked by CAMP [ 1,2,6]. The effect of hormonal stimuli on K’ flux is biphasic, consisting of an initial uptake of K’, followed by release when the liver plasma membrane hyperpolarizes [7-91. The efflux of K’ and the associated hyperpolarization have been attributed to an increase in the K+ permeability of the liver cell membrane [7,8]. The uptake phase has been less studied and conflicting results on hormonal effects on Na’ fluxes render the mechanism responsible for it less clear. Gluconeogenic hormones have been reported to cause Na’ release [lo], uptake followed by release [ 11, uptake [7] or to have no effect on Na’ movements. Since K’ uptake occurs against a concentration gradient, we undertook to determine whether gluconeogenic hormones promote K+ uptake by activating the membrane-bound Na’,K’-ATPase. Here, gluconeogenie hormones are shown to stimulate the enzyme. Insulin, which antagonizes the effect of the gluconeogenie hormones [6], had no similar effect, but prevented the stimulation by glucagon.

Constituents of human meconium—I. Identification of 3-hydroxy-etianic acids

The monohydroxylated fraction of bile acids of human meconium was analyzed by capillary GC-MS. In the sulfate-glucuronide fraction three saturated, and one unsaturated C20 steroidal acids were found. These acids were identified as 3 alpha-hydroxy-5 alpha-, 3 alpha-hydroxy-5 beta-,3 beta-hydroxy-5 alpha-androstane-17 beta-carboxylic, and 3 beta-hydroxyandrost-5-ene-17 beta-carboxylic based on the unequivocal GC-MS comparison with standards of all possible epimers at C-3, 5 and 17. The amount of the major C20 acid, 3 alpha-hydroxy-5 alpha-androstane-17 beta-carboxylic, in meconium was 0.2 nmol/g, i.e. 5 to 10 times the amount of lithocholic acid. To prevent the oxidation of 21-hydroxy-20-oxopregnanes to C20 acids meconium was extracted in the presence of sodium borohydride. In the absence of this reducing agent the amount of 3 beta-hydroxyandrost-5-ene-17 beta-carboxylic acid was increased and its 17 alpha-epimer could be detected. This indicates partial artifactual formation of this C20 acid from 21-hydroxypregnenolone, which is known to be present in human meconium. The amount of the saturated C20 acids was unaffected by the presence of sodium borohydride in the extraction medium, and their native occurence in human meconium was further confirmed by the absence of their 17 alpha-epimers in extracts obtained both with and without borohydride. The probable metabolic origin of C20 acids in the fetal-placental-maternal unit is discussed.

Bile salt-induced calcium fluxes in artificial phospholipid vesicles

The ionic permeability of selected biological membranes is increased by bile salts. To examine changes in calcium permeability during the exposure of artificial membranes to bile salts, we investigated calcium uptake by unilamellar and multilamellar phospholipid vesicles. In the presence of 750 microM taurodeoxycholate, uptake of radiolabelled calcium by unilamellar vesicles increased 2.5-fold over control values. Calcium uptake by multilamellar vesicles as measured with a free calcium indicator, arsenazo III, increased 2.2- or 21-fold in the presence of 60 microM lithocholate or 3 beta-hydroxy-5-cholenoate, respectively. Results were directly influenced by experimental variables such as bile salt hydrophobicity, external calcium concentration, and the bile salt/lipid molar ratio. Observed membrane solubilization was minimal despite increased calcium permeability. Comparison of radiolabelled calcium uptake with radiolabelled sodium or radiolabelled rubidium uptake indicated that bile salt-dependent calcium uptake was 60-140-times greater than bile salt-dependent uptake of either monovalent cation. In an effort to delineate forces affecting calcium translocation, vesicles were exposed either to valinomycin, which induced an electrochemical gradient across the membrane, or to nigericin, which induced a proton gradient. Exposure to valinomycin minimally influenced bile salt-induced calcium uptake while exposure to nigericin significantly promoted uptake by 40-70%. The results suggest that bile salts promote calcium uptake by a mechanism which may be similar to those of other carboxylic ionophores.

Constituents of human meconium: II. Identification of steroidal acids with 21 and 22 carbon atoms

Monohydroxylated acid fraction isolated from human meconium was found to contain, in addition to C20 and C24 acids identified previously, three C22 bile acids-(20S)-3α-hydroxy-23,24-bisnor-5β-cholan-22-oic, (20S)- and (20R)-3β-hydroxy-23,24-bisnor-chol-5-en-22-oic, and one C21 acid-3β-hydroxypregn-5-en-21-oic. These compounds were identified by capillary gas chromatography-mass spectrometry and by comparison with standards. It is postulated that these C22 acids, as well as the two monohydroxylated C24 bile acids (lithocholic and 3β-hydroxychol-5-enoic) are produced in the maternal intestine by microbial flora and transferred to the fetus through the placenta.

Hepatic metabolism of 3 alpha-hydroxy-5 beta-etianic acid (3 alpha-hydroxy-5 beta-androstan-17 beta-carboxylic acid) in the adult rat.

Normal human meconium has been shown to contain short-chain (C20-C22) bile acids and, recently, these compounds have been identified in sera of patients with cholestasis. This suggests that shortchain bile acids may be secreted in bile. We have examined this point by studying the hepatic metabolism and biliary secretion of one naturally occurring C20 bile acid, 3 alpha-hydroxy-5 beta-etianic acid (3 alpha-hydroxy-5 beta-androstan-17 beta-carboxylic acid). [3-3H]-3 alpha-hydroxy-5 beta-etianic acid was prepared and administered intravenously to rats prepared with an external biliary fistula. 85.5 +/- 1.2% of the administered dose was recovered in bile over 20 h with 71.5 +/- 1.3% appearing in the first hour. 11.9 +/- 1.6% of the dose was estimated to be distributed in body water and 0.6 +/- 0.2% was recovered as organic matter in urine. Total recovery of label was 98.0 +/- 2.6%. Administration of milligram quantities of 3 alpha-hydroxy-5 beta-etianic acid produced an increase in bile flow (58.9 +/- 7.1% over basal levels) within 20 min after injection of the steroid. The radiolabeled material in bile was shown by thin-layer chromatography (TLC) to be a polar conjugate which, after beta-glucuronidase hydrolysis, cochromatographed with authentic free 3 alpha-hydroxy-5 beta-etianic acid. After purification, and derivatization, the steroid moiety was proven by gas chromatography-mass spectrometry to be identical to 3 alpha-hydroxy-5 beta-etianic acid. Characterization of the conjugate by TLC and by 3 alpha-hydroxysteroid dehydrogenase assay, before and after beta-glucuronidase hydrolysis, indicated that the steroid was secreted in bile as the 3-O-beta-glucuronide. It is concluded that 3 alpha-hydroxy-5 beta-etianic acid is cleared from the plasma, conjugated with glucuronic acid, and secreted into bile rapidly and in high concentration. The choleretic properties of this shortchain bile acid contrast with the cholestatic effects of lithocholic acid, its C24 analog. Both the form of conjugation of etianic acid and its effect on bile flow suggest that the shortened side chain of this steroid markedly alters its hepatic metabolism and physiology.

Intestinal absorption of bile acid glucuronides in rats

While the intestinal absorption of taurine, glycine, and sulfate conjugates of bile acids has been studied extensively, nothing is known about the absorption of bile acid glucuronides. In the present study, the intestinal phase of the enterohepatic circulation of two bile acid glucuronides was examined. [3β-3H]cholic acid 3-O-β-d-glucuronide or [3β−3H]lithocholic acid 3-O-β-d-glucuronide was perfused through isolated segments of ileum or jejunum with intact blood supply in rats prepared with a biliary fistula. [14C]Taurocholic acid was perfused simultaneously with each glucuronide to compare glucuronide absorption with that of an actively transported bile acid. Intestinal absorption was determined by measuring the rate of secretion of labeled bile acid in bile. The absorption of [3H]cholic acid glucuronide by the ileum and jejunum was one fortieth and one eighth, respectively, that of [14C]taurocholic acid. Comparison of the two glucuronides show that [3H]lithocholic acid glucuronide absorption was 18 and 10 times greater than [3H]cholic acid glucuronide absorption from the jejunum and ileum, respectively. Collectively, the above observations suggest that glucuronidation of bile acids markedly reduces absorption from the small intestine.