Biliary excretion of inorganic electrolytes: its role in hepatic bile formation

To define the role of inorganic electrolyte secretion in hepatic bile formation, the effects of secretin, glucagon, and differently structured bile acids on bile flow and composition were studied in the dog, guinea pig, and rat. In the dog and guinea pig, secretin (2.5-10 clinical units X kg-1 X 30 min-1) increased bile flow and bicarbonate concentration in bile, a finding consistent with the hypothesis that the hormone stimulates a bicarbonate-dependent secretion possibly at the level of the bile ductule-duct. In the rat, secretin (5-15 CU X kg-1 X 30 min-1) failed to increase bile secretion. Glucagon (1.25-300 micrograms X kg-1 X 30 min-1) increased bile flow in all the three species, and produced no changes in biliary bicarbonate concentrations in the dog and rat. In the guinea pig, however, glucagon choleresis was associated with an increase in bicarbonate concentration in bile, similar to that observed with secretin. The choleretic activities of various bile acids (taurocholate, chenodeoxycholate, glycochenodeoxycholate, tauroursodeoxycholate, and ursodeoxycholic acid, infused at 30-360 mumol X kg-1 X 30 min-1) were similar in the rat (6.9-7.2 microL/mumol), but different in the guinea pig (11-31 microL/mumol). In the latter species, the more hydrophobic the bile acid, the greater was its choleretic activity. In all instances, bile acid choleresis was associated with a decline in the biliary concentrations of chloride, but with no major change in bicarbonate levels.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bile acid structure and bile formation in the guinea pig

The effects of intravenous infusions (1-4 mumol/min/kg) of 14 bile acids, cholic, deoxycholic, ursodeoxycholic, chenodeoxycholic, dehydrocholic, and their glycine and taurine conjugates, on bile flow and composition and on the biliary permeation of inert carbohydrates have been studied in the guinea pig bile fistula. Hydroxy bile acids were eliminated in bile without major transformation, except for conjugation (over 90%) when unconjugated bile acids were infused. During infusion of dehydrocholate and taurodehydrocholate, 77-100% of the administered dose was recovered in bile as 3-hydroxy bile acids, thus indicating that reduction of the keto group in position 3 was virtually complete. All bile acids produced choleresis at the doses employed: the strongest choleretic was deoxycholate (81.78 microliters/mumol), the weakest was taurodehydrocholate (10.2 microliters/mumol). Choleretic activity was directly and linearly related to bile acid hydrophobicity, as inferred by HPLC, both for similarly conjugated bile acids, and for bile acids having the same number, position, or configuration of the hydroxyl groups. In all instances, the rank ordering was: deoxycholate greater than chenodeoxycholate greater than cholate greater than ursodeoxycholate. During choleresis produced by any of the bile acids tested, bicarbonate concentration in bile slightly declined, but the calculated concentration in bile-acid-stimulated bile (45-57 mmol/l) was always higher than that measured in plasma (23-26 mmol/l). Biliary concentrations of cholesterol (20-68 mumol/l) and phospholipid (14-63 mumol/l) were very low during spontaneous secretion, and declined even further following bile acid choleresis. None of the infused bile acids consistently modified biliary excretion of cholesterol and phospholipid. Consistent with a previous observation from this laboratory, all hydroxy bile acids reversibly diminished [14C]erythritol and [14C]mannitol biliary entry during choleresis, while they increased or failed to modify that of [3H]sucrose and [3H]inulin. The rank ordering for the inhibitory effect on [14C]erythritol and [14C]mannitol permeation was: 3 alpha,7 alpha,12 alpha-trihydroxy greater than 3 alpha,7 alpha-dihydroxy greater than 3 alpha,7 beta-dihydroxy greater than 3 alpha,12 alpha-dihydroxy bile acids.(ABSTRACT TRUNCATED AT 400 WORDS)     

Insulin or glucagon choleresis in the isolated perfused guinea pig liver

Insulin and glucagon choleresis was studied in an in situ, isolated perfused guinea pig liver system. Glucagon caused a small, significant increase in bile salt independent flow (1.83 +/- 0.19 to 2.02 +/- 0.23 microliter g-1 min-1), and dose-related increments over 2-16 micrograms were observed. Insulin alone had no choleretic effect. However, the combination of insulin and glucagon caused a response (1.89 +/- 0.15 to 2.42 +/- 0.19) greater than glucagon alone, and insulin stimulated choleresis when glucagon was present in substimulatory amounts. These observations demonstrate direct effects of glucagon and insulin upon the bile secretory apparatus. Glucagon directly stimulates choleresis, while insulin acts more subtly by potentiation with glucagon.     

Anti-cholestatic activity of HD-03, a herbal formulation in thioacetamide (TAA)-induced experimental cholestasis

In the present study HD-03, a herbal formulation was investigated for its anti-cholestatic activity in TAA-induced cholestasis in anaesthetized guinea pigs. Administration of TAA at a dose of 100 mg/kg body wt significantly reduced the bile flow, bile acid and bile salt excretion. Pretreatment with HD-03 at a dose of 750 mg/kg body wt per orally for 15 days in guinea pigs significantly prevented thioacetamide-induced changes in bile flow, bile acids and bile salts excretion. Thus, HD-03 can serve as a potent choleretic and anti-cholestatic agent.     

Quantitative estimation of the hydrophilic-hydrophobic balance of mixed bile salt solutions

This paper describes the derivation of a bile salt monomeric hydrophobicity index that quantitatively defines the composite hydrophilic-hydrophobic balance of a mixture of bile salts. The index is based on the logarithms of bile salt capacity factors determined using reversed phase high performance liquid chromatography (HPLC) (stationary phase octadecyl silane; mobile phase methanol-water 70:30 w/w, ionic strength 0.15). It has been standardized arbitrarily to set indices of taurocholate and taurolithocholate to 0 and 1, respectively. Indices of tauroursodeoxycholate, taurohyodeoxycholate, taurochenodeoxycholate, and taurodeoxycholate were found to be -0.47, -0.35, +0.46, and +0.59, respectively. Whereas capacity factors and hydrophobicity indices of taurine-conjugated bile salts were constant for pH 2.8-9.0, the hydrophilic-hydrophobic balance of glycine-conjugated and unconjugated bile salts was strongly influenced by pH. At alkaline pH (greater than 8.5), hydrophobicity indices of fully ionized unconjugated (n = 4) and glycine-conjugated (n = 6) bile salts differed by only 0.14 +/- 0.02 and 0.05 +/- 0.01, respectively, from those of the corresponding taurine conjugates. At acid pH (less than 3.5) the hydrophobicity indices of four unconjugated bile acids (protonated form) exceeded those of the corresponding salts (ionized form) by 0.76 +/- 0.04; indices of six glycine-conjugated bile acids exceeded those of the corresponding salts by only 0.26 +/- 0.03. Capacity factors of the salt forms of cholate and its conjugates increased dramatically with increasing ionic strength of the mobile phase; retention of the protonated forms (cholic and glycocholic acids) was only minimally influenced by ionic strength. Thus the difference in hydrophilic-hydrophobic balance between a bile acid and its corresponding salt decreases with increasing ionic strength. Examples are given of calculation of hydrophobicity indices for biliary bile salts (fully ionized) from four species under conditions of intact enterohepatic circulation. Mean values, from least to most hydrophobic, were: rat (-0.31) less than dog (0.11) less than hamster (0.22) less than human (0.32). This study provides a rational basis for calculating the hydrophilic-hydrophobic balance of mixed bile salt solutions over a broad range of pH.     

Regulation of biliary protein secretion in dogs

The biliary secretion of protein in response to bile acids and other agents known to increase bile flow was examined in a chronic bile fistula dog model. Infusion of 25, 50, or 75 mumole/kg/hr sodium taurocholate after 3 hr of bile fistulization increased biliary protein output significantly by 52, 86, and 108% respectively compared to preinfusion values. A proportionate increase in biliary albumin output during taurocholate choleresis was demonstrated. Protein outputs during bile fistulization without taurocholate replacement were unchanged. The non-micelle-forming bile acid dehydrocholate markedly increased bile flow but did not change protein output. Similarly, the hormonal choleretics glucagon and secretin caused significant decreases in biliary protein concentration but no change in protein output. These data indicate a correlation between biliary protein secretion and bile acid-dependent bile flow. It is likely that regulation of certain proteins is dependent on the micelle-forming properties of bile acids.     

Effects of bile acids on actin polymerization in vitro

Bile acids are major determinants of canalicular bile secretion, and there are indications that choleretic bile acids increase bile canalicular contractions, in isolated rat hepatocytes. Therefore, we examined the influence of various bile acids on the rate of actin polymerization in vitro. The free forms of cholic acid, ursodeoxycholic acid, and chenodeoxycholic acid, as well as their taurine and glycine conjugates, were incubated with purified muscle actin, at a concentration of 100-300 nmoles/mg actin. The rate of actin polymerization was measured by viscometry and the fluorescence of the pyrene probe, linked to actin. Results showed that all bile acids slow the rate of polymerization, and that the effect was dose-dependent. However, the reduction by chenodeoxycholic acid was greater than that caused by the other bile acids. The results indicate that bile acids, particularly in high concentrations interact with actin, a finding that may be related to the increased bile canalicular contractility, and altered canalicular membrane morphology, induced by choleretic bile acids.     

Bile acid secretion and pool size during phenobarbital induced hypercholeresis

An increase in bile flow after phenobarbital administration occurs in the rat and other species; however, the mechanism(s) of the choleretic effect is incompletely understood and the role of the increase in liver weight is controversial. We therefore measured bile flow, bile acid secretion and pool size in male Sprague-Dawley rats pretreated with phenobarbital (75 mg/kg/day) for 6 days; liver weight, liver cell volume and DNA content were also evaluated. Phenobarbital treatment increased liver weight and mean hepatocyte volume by 39 and 26%, respectively, while total DNA content did not change, thus indicating that the hepatomegaly results principally from hypertrophy rather than hyperplasia. Bile flow was significantly higher in treated rats when expressed per unit of body weight (64.6 +/- 2.4 (S.E.) vs 53.3 +/- 1.6 microliter/min/kg; P less than 0.05) but was unchanged when expressed per gram of liver (1.40 +/- 0.04 vs 1.37 +/- 0.06 microliter/min/g; P greater than 0.5). The initial bile acid secretion rate and pool size were both significantly reduced in the phenobarbital group compared to controls (1224.2 +/- 110.4 vs 1656.6 +/- 163.2 nmol/kg/min and 562.8 +/- 41.5 vs 814.3 +/- 78.3 mumol/kg; both P less than 0.05), whereas the basal synthetic rate was unchanged. These findings suggest that the enlarged, phenobarbital-treated hepatocyte produces more bile than the normal cell, despite the decreased secretion of bile acids. Therefore, the drug-induced choleresis involves a selective increase in the bile acid-independent fraction of bile flow.     

Solubility of calcium salts of unconjugated and conjugated natural bile acids.

The approximate solubility products of the calcium salts of ten unconjugated bile acids and several taurine conjugated bile acids were determined. The formation of micelles, gels, and/or precipitates in relation to Ca2+,Na+, and bile salt concentration was summarized by "phase maps." Because the ratio of Ca2+ to bile salt in the precipitates was ca. 1:2, and the activity of Ca2+ but not that of bile salt (BA-) could be measured, the ion product of aCa2+ [BA-]2 was calculated. The ion product (= Ksp) ranged over nine orders of magnitude and the solubility thus ranged over three orders of magnitude; its value depended on the number and orientation of the hydroxyl groups in the bile acid. Ion products (in units of 10(-9) mol/l)3 were as follows: cholic (3 alpha OH,7 alpha OH,12 alpha OH) 640; ursocholic (3 alpha OH,7 beta OH,12 alpha OH) 2300; hyocholic (3 alpha OH,6 alpha OH,7 alpha OH) 11; ursodeoxycholic (3 alpha OH,7 beta OH) 91; chenodeoxycholic (3 alpha OH,7 alpha OH) 10; deoxycholic (3 alpha OH,12 alpha OH) 1.5; 12-epideoxycholic (lagodeoxycholic, 3 alpha OH,12 beta OH) 2.2; hyodeoxycholic (3 alpha OH,6 alpha OH) 0.7; and lithocholic (3 alpha OH) 0.00005. The critical micellization temperature of the sodium salt of murideoxycholic acid (3 alpha OH,6 beta OH) was greater than 100 degrees C, and its Ca2+ salt was likely to be very insoluble. Taurine conjugates were much more soluble than their corresponding unconjugated derivatives: chenodeoxycholyltaurine, 384; deoxycholyltaurine, 117; and cholyltaurine, greater than 10,000. Calcium salts of unconjugated bile acids precipitated rapidly in contrast to those of glycine conjugates which were metastable for months. Thus, hepatic conjugation of bile acids with taurine or glycine not only enhances solubility at acidic pH, but also at Ca2+ ion concentrations present in bile and intestinal content.     

First synthesis of phosphonobile acids and preliminary studies on their aggregation properties

The synthesis of three novel phosphonobile acids from natural bile acids is reported. The CMC of phosphonodeoxycholic acid (PDCA) at pH 8.2 was found to be lower than that of the parent deoxycholic acid (DCA). PDCA micelles were also found to have higher microviscosity compared to DCA micelles, suggesting higher hydrophobicity and tighter packing in the interior of PDCA micelles. PDCA aggregated further to form an aqueous gel at pH 4.     

Solubilization of lipids from hamster bile-canalicular and contiguous membranes and from human erythrocyte membranes by conjugated bile salts.

We have demonstrated in vitro the efficacy of the taurine-conjugated dihydroxy bile salts deoxycholate and chenodeoxycholate in solubilizing both cholesterol and phospholipid from hamster liver bile-canalicular and contiguous membranes and from human erythrocyte membrane. On the other hand, the dihydroxy bile salt ursodeoxycholate and the trihydroxy bile salt cholate solubilize much less lipid. The lipid solubilization by the four bile salts correlated well with their hydrophobicity: glycochenodeoxycolate, which is more hydrophobic than the tauro derivative, also solubilized more lipid. All the dihydroxy bile salts have a threshold concentration above which lipid solubilization increases rapidly; this correlates approximately with the critical micellar concentration. The non-micelle-forming bile salt dehydrocholate solubilized no lipid at all up to 32 mM. All the dihydroxy bile acids are much more efficient at solubilizing phospholipid than cholesterol. Cholate does not show such a pronounced discrimination. Lipid solubilization by chenodeoxycholate was essentially complete within 1 min, whereas that by cholate was linear up to 5 min. Maximal lipid solubilization with chenodeoxycholate occurred at 8-12 mM; solubilization by cholate was linear up to 32 mM. Ursodeoxycholate was the only dihydroxy bile salt which was able to solubilize phospholipid (although not cholesterol) below the critical micellar concentration. This similarity between cholate and ursodeoxycholate may reflect their ability to form a more extensive liquid-crystal system. Membrane specificity was demonstrated only inasmuch as the lower the cholesterol/phospholipid ratio in the membrane, the greater the fractional solubilization of cholesterol by bile salts, i.e. the total amount of cholesterol solubilized depended only on the bile-salt concentration. On the other hand, the total amount of phospholipid solubilized decreased with increasing cholesterol/phospholipid ratio in the membrane.     

Pancreatic lipase activity as influenced by unconjugated bile acids and pH,measured in vitro and in vivo

The relation between pancreatic lipase activity, unconjugated bile acids and pH was studied in vitro and in vivo. Lipase activity was assayed in vitro using automatic titration, where the fatty acids liberated from the hydrolysis of glycerol tributyrate (GTB) were measured. The lipase activity was determined at different ratios of conjugated to unconjugated bile acids (100:0, 75:25, 50:50, 25:75, 0:100) in response to pH 6.6, 6.8, 7.0 and 7.5. The in vivo study involved 96 one-day-old male broiler chickens. The chickens were assigned randomly, in pens of six animals, into two dietary treatments (8 replicate blocks), composing a non-supplemented diet (A(-)) and a diet supplemented (A(+)) with avilamycin (10 mg/kg feed) and salinomycin (40 mg/kg feed). After 35 days, the chickens were killed and content of the proximal part of the small intestine was collected and analyzed for bacterial counts, pH, bile acid concentration, and lipase activity. Evidence for a significant pH-dependent inhibition of lipase activity by unconjugated bile acids was provided in vitro and confirmed in vivo. Due to a reduction in nutrient fermentation, the pH in the small intestine of antibiotic-fed chickens was significantly higher than in chickens fed the non-supplemented diet. The high pH in the small intestine of chickens fed the A(+)diet was accompanied by a significant increase in lipase activity, and coincided with a significantly lower concentration of unconjugated bile acids and a higher ratio of conjugated to unconjugated bile acids. This study emphasizes the important influence of unconjugated bile acids on lipase activity at physiological pH-values.     

Hydrophobicity and haemolytic potential of oxo derivatives of cholic, deoxycholic and chenodeoxycholic acids

The objective of this work was to study the effect of structure of bile acids on their membranolytic potential and extent of overlapping of the information about the membranolytic potential of bile acids and their physico-chemical parameters, namely: retention index R_M0 (as a measure of bile acid hydrophobicity, reversed-phase thin-layer chromatography (RPTLC)), lecithin solubilisation (measure of the interaction of bile acids with phospholipids) and critical micellar concentration (CMC).It was found that bile acid concentrations at 100% lysis of erythrocyte membranes is described best by their CMC values, whereas at 50% lysis the parameter used is lecithin solubilisation. This indicates that different mixed micelles are formed in the membrane lysis at lower and higher concentrations of bile acids. Replacement of the hydroxyl (OH) group in the bile acid molecule with an oxo group yields derivatives with lowered hydrophobicity, power of lecithin solubilisation, tendency for self-aggregation as well as the membranolytic activity.     

Synthesis of the 3-sulfates of S-acyl glutathione conjugated bile acids and their biotransformation by a rat liver cytosolic fraction

The 3-sulfates of the S-acyl glutathione (GSH) conjugates of five natural bile acids (cholic, chenodeoxycholic, deoxycholic, ursodeoxycholic, and lithocholic) were synthesized as reference standards in order to investigate their possible formation by a rat liver cytosolic fraction. Their structures were confirmed by proton nuclear magnetic resonance, as well as by means of electrospray ionization-linear ion-trap mass spectrometry with negative-ion detection. Upon collision-induced dissociation, structurally informative product ions were observed. Using a triple-stage quadrupole instrument, selected reaction monitoring analyses by monitoring characteristic transition ions allowed the achievement of a highly sensitive and specific assay. This method was used to determine whether the 3-sulfates of the bile acid-GSH conjugates (BA-GSH) were formed when BA-GSH were incubated with a rat liver cytosolic fraction to which 3'-phosphoadenosine 5'-phosphosulfate had been added. The S-acyl linkage was rapidly hydrolyzed to form the unconjugated bile acid. A little sulfation of the GSH conjugates occurred, but greater sulfation at C-3 of the liberated bile acid occurred. Sulfation was proportional to the hydrophobicity of the unconjugated bile acid. Thus GSH conjugates of bile acids as well as their C-3 sulfates if formed in vivo are rapidly hydrolyzed by cytosolic enzymes.     

Differential stimulation of S-adenosylmethionine decarboxylase by difluoromethylornithine in the rat colon and small intestine.

The effects of sodium cyclobutyrate, a synthetic hydrocholeretic drug, on biliary lipid secretion and on the biliary outputs of several plasma-membrane enzymes were investigated in anaesthetized rats. Administration of a single oral dose of cyclobutyrol (0.72 mmol/kg body wt.) reduced biliary concentration and output of cholesterol and phospholipid. However, bile acid secretion was not significantly modified. This uncoupling effect of lipid secretion remained even when the choleretic response to the drug had ceased. It additionally led to a statistically significant decrease in the cholesterol/bile acid and phospholipid/bile acid molar ratios and in the lithogenic index of the bile. The biliary outputs of the plasma-membrane enzymes alkaline phosphatase and gamma-glutamyltransferase were markedly reduced by the drug. When cyclobutyrol was administered to rats which had been previously fed with a high-cholesterol diet, the effects of cyclobutyrol persisted, but were less marked. Our results demonstrate that the bile acid-independent choleresis induced by cyclobutyrol (related to its pharmacokinetic effect) is accompanied by a pharmacodynamic action that selectively reduces the secretion of biliary lipids. This is due to an uncoupling of the secretion of cholesterol and phospholipids from that of bile acids. Possible explanations for the biliary response to cyclobutyrol are discussed.     

The ionization behavior of bile acids in different aqueous environments

The ionization behavior of cholic acid, deoxycholic acid, and chenodeoxycholic acid in a variety of physiologically important molecular environments was studied using 13C NMR spectroscopy. The apparent pKa of the carboxyl group was determined from titration curves obtained from the dependence of the carboxyl carbon chemical shift on pH. Using 90% 13C isotopic substitution of the carboxyl carbon, a complete titration curve was obtained for cholate at a concentration below its critical micelle concentration and solubility limit in water. Incorporation of 12 mole % bile acid into mixed micelles with its taurine conjugate prevented precipitation of the unconjugated bile acid, and titration curves for cholic, deoxycholic, and chenodeoxycholic acids in the mixed micelles were obtained. The apparent pKa was also determined for 13C-enriched bile acids complexed with bovine serum albumin and in egg phosphatidylcholine vesicles. For monomers, micelles, and BSA complexes of all three bile acids and for deoxycholic and chenodeoxycholic acid in vesicles, one magnetic environment was observed. In contrast, two environments, both titratable, were detected for cholic acid in phosphatidylcholine vesicles. The apparent pKa's of the bile acids in the different environments ranged from 4.2 to 7.3. At pH 7.4, as monomers or bound to albumin, the bile acids were fully ionized, but when associated with phosphatidylcholine vesicles they were only partially ionized. In addition, aspects of the molecular motion and relative hydrophobicity of the bile acid carboxyl group in the environments studied were discerned from chemical shift, line-width, and lineshape data.     

Bile acid structure-activity relationship: evaluation of bile acid lipophilicity using 1-octanol/water partition coefficient and reverse phase HPLC

Two independent methods have been developed and compared to determine the lipophilicity of a representative series of naturally occurring bile acids (BA) in relation to their structure. The BA included cholic acid (CA), chenodeoxycholic acid (CDCA), ursodeoxycholic acid (UDCA), deoxycholic acid (DCA), hyodeoxycholic acid (HDCA), ursocholic acid (UCA), hyocholic acid (HCA), as well as their glycine and taurine amidates. Lipophilicity was determined using a 1-octanol/water shake-flask procedure and the experiments were performed at different pH and ionic strengths and at initial BA concentrations below their critical micellar concentrations (CMC) and the water solubility of the protonated form. The experimental data show that both the protonated (HA) and ionized (A-) forms of BA can distribute in 1-octanol, and consequently a partition coefficient for HA (logP' HA) and for A- (logP' A-) must be defined. An equation to predict a weighted apparent distribution coefficient (D) value as a function of pH and pKa has been developed and fits well with the experimental data. Differences between logP for protonated and ionized species for unconjugated BA were in the order of 1 log unit, which increased to 2 for glycine-amidate BA. The partition coefficient of the A- form increased with Na+ concentration and total ionic strength, suggesting an ion-pair mechanism for its partition into 1-octanol. Lipophilicity was also assessed using reverse phase chromatography (C-18-HPLC), and a capacity factor (K') for ionized species was determined. Despite a broad correlation with the logP data, some BA behaved differently. The logP values showed that the order of lipophilicity was DCA greater than CDCA greater than UDCA greater than HDCA greater than HCA greater than CA greater than UCA for both the protonated and ionized unconjugated and glycine-amidate BA, while the K' data showed an inversion for some BA, i.e., DCA greater than CDCA greater than CA greater than HCA greater than UDCA greater than HDCA greater than UCA. The logP data fitted well with other indirect measurements of BA monomeric lipophilicity such as albumin binding or accessible total hydrophobic surface area data calculated by energy minimization and molecular computer graphics. Differences between unconjugated and amidated BA are consistent with the presence of an amide bond and a lower pKa when pH dependence was studied. Capacity factors, on the other hand, were related to properties of BA micelles such as cholesterol-solubilizing capacity and membrane disruption, reflecting the BA detergency.(ABSTRACT TRUNCATED AT 400 WORDS)     

Bile acid: CoASH ligases from guinea pig and porcine liver microsomes. Purification and characterization

A procedure for the purification of the enzyme bile acid:CoA ligase from guinea pig liver microsomes was developed. Activity toward chenodeoxycholate, cholate, deoxycholate, and lithocholate co-purified suggesting that a single enzyme form catalyzes the activation of all four bile acids. Activity toward lithocholate could not be accurately assayed during the earlier stages of purification due to a protein which interfered with the assay. The purified ligase had a specific activity that was 333-fold enriched relative to the microsomal cell fraction. The purification procedure successfully removed several enzymes that could potentially interfere with assay procedures for ligase activity, i.e. ATPase, AMPase, inorganic pyrophosphatase, and bile acid-CoA thiolase. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis the purified ligase gave a single band of approximately 63,000 Mr. A molecular size of 116,000 +/- 4,000 daltons was obtained by radiation inactivation analysis of the ligase in its native microsomal environment, suggesting that the functional unit of the ligase is a dimer. The purified enzyme was extensively delipidated by adsorption to alumina. The delipidated enzyme was extremely unstable but could be partially stabilized by the addition of phospholipid vesicles or detergent. However, such additions did not enhance enzymatic activity. Kinetic analysis revealed that chenodeoxycholate, cholate, deoxycholate, and lithocholate were all relatively good substrates for the purified enzyme. The trihydroxy bile acid cholate was the least efficient substrate due to its relatively low affinity for the enzyme. Bile acid:CoA ligase could also be solubilized from porcine liver microsomes and purified 180-fold by a modification of the above procedure. The final preparation contains three polypeptides as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The three peptides range in size from 50,000 to 59,000, somewhat smaller than the guinea pig enzyme. The functional size of the porcine enzyme in its native microsomal environment was determined by the technique of radiation inactivation analysis to be 108,000 +/- 5,000 daltons. Thus, the functional form of the porcine enzyme also appears to be a dimer.     

Aminopeptidase M from human liver. I. Solubilization, purification, and some properties of the enzyme

Aminopeptidase M [EC 3.4.11.2] was purified 772-fold to homogeneity from the microsomal fraction of human liver, with a yield of 18.9%, by a combination of solubilization with 0.5% Triton X-100 and then 1 M urea and chromatography on columns of DEAE-cellulose, hydroxylapatite, Butyl-Toyopearl, and Sephacryl S-300. The purified enzyme had a molecular weight of 140,000 by SDS-polyacrylamide gel electrophoresis and of 280,000 by gel filtration on a column of TSK gel 2000 SW. It was reconstituted into proteoliposomes with asolectin, showing its amphiphilic nature. The aminopeptidase M from liver was found to be efficiently inhibited by bile acids. The enzyme was almost completely inhibited by chenodeoxycholic acid and 70-90% inhibited by cholic acid at a concentration of 6 mM. The extent of inhibition by conjugated and unconjugated bile acids was in the order: unconjugated greater than glycoconjugated greater than tauroconjugated bile acid, independent of the nature of the substrates used. The inhibition by the various bile acids was totally reversible. Further, it was immunochemically revealed that a considerable amount of liver aminopeptidase M was released into the bile duct. The role of the aminopeptidase M on the bile canalicular membrane and of the enzyme released in the bile duct is discussed in relation to the effects of bile acids.     

Metabolism of two hydroxy-7-oxocholanic acids in isolated perfused rat liver

The metabolism of 7-oxolithocholic acid and 7-oxodeoxycholic acid in isolated perfused rat livers was compared. The metabolites extracted from the bile of perfused livers were analysed by gas chromatography. The amount of bile acids excreted in bile was greater after infusion with 7-oxolithocholic acid than with 7-oxodeoxycholic acid. When 7-oxolithocholic acid was infused almost all of the bile acids excreted in bile were taurine conjugates; with 7-oxodeoxycholic acid about 10 percent remained unconjugated. 7-Oxolithocholic acid was more susceptible to reduction than 7-oxodeoxycholic acid. 7-Oxolithocholic acid was preferably reduced to 7 beta-hydroxy rather than to 7 alpha-hydroxy metabolites. In contrast, 7-oxodeoxycholic acid was reduced predominantly to the 7 alpha-hydroxy rather than to the 7 beta-hydroxy metabolite.