Comparison of the binding sites of GSH S-transferases of the Ya- and Yb-subunit classes: effect of glutathione on the binding of bile acids

We have previously observed that the Ya subunit-containing glutathione (GSH) S-transferases from rat liver exhibit a common high affinity binding site for lithocholic acid, bilirubin, and sulfobromophthalein (BSP) (1984. J. Lipid Res. 25: 1177-1183). Subsequently we found that cholic acid and its amidates bound to a site on the Ya subunit separate for the lithocholic acid/bilirubin site (1986. J. Lipid Res. 27: 955-966). We now have extended this work by showing that amidates of lithocholic acid as well as chenodeoxycholic acid and its amidates competitively displace [14C]lithocholic acid from the Ya subunit. GSH did not inhibit binding of any of the ligands to the high affinity Ya site, but did inhibit binding to the cholic acid site on the Ya subunit. We have also defined the binding sites and effects of GSH on the Yb class of subunits. Lithocholic, chenodeoxycholic, and cholic acids (and amidates) shared a common site on the Yb or Y'b subunit, whereas BSP and bilirubin were bound at a different site. Both the bile acid and organic anion sites on the Yb subunit were inhibited by GSH. The inhibition by GSH in all cases (Ya cholic acid site or Yb bile acid or bilirubin sites) was saturable, of the competitive type, and incomplete at maximal GSH concentrations, suggesting that when GSH binds to its distinct substrate site, it induces a conformational change in the proteins affecting the other binding sites.     

A study of the structures of the YaYa and YaYc glutathione S-transferases from rat liver cytosol. Evidence that the Ya monomer is responsible for lithocholate-binding activity.

The two dimeric lithocholic acid-binding proteins previously identified as ligandin (YaYa) and glutathione S-transferase B (YaYc) were isolated from rat liver cytosol. These proteins have molecular weights of 44000 and 47000 respectively. The recovery of these two proteins from liver was not affected by the addition of the proteinase inhibitor Trasylol. No spontaneous interconversion between these two proteins was observed on storage. YaYa and YaYc proteins yielded peptides of identical molecular weight after limited digestion with Staphylococcus aureus V8 proteinase. Analytical and preparative tryptic-digest peptide 'maps' showed that all the soluble peptides obtained from YaYa protein were also recovered from YaYc protein. Approximately six extra soluble peptides, which were not recovered from YaYa protein, were obtained from the tryptic digest of YaYc protein. Subdigests of the insoluble tryptic-digest 'cores' also resulted in the recovery of identical peptides from both proteins. Evidence is presented that the Ya subunit possessed by both proteins is identical; glutathione S transferase B is a hybrid of ligandin and glutathione S-transferase AA. The Ya monomer is responsible for lithocholate binding.     

Multiple Ya subunits of glutathione S-transferase detected by monoclonal antibodies

Monoclonal antibodies to ligandin (YaYa) and glutathione (GSH) S-transferase B (YaYc) were produced by hybridomas derived from the fusion of mouse myeloma cells and spleen cells of mice immunized with the YaYa or YaYc proteins, respectively. Enzyme-linked immunosorbent assay was used to screen for antibody-producing clones. Immunoblotting of the subunits of transferase B, ligandin, and another GSH S-transferase containing Yb subunits showed that the monoclonal antibodies produced by two anti-YaYa subclones recognized the Ya subunits of both ligandin and transferase B, but they did not bind Yc or Yb subunits. It was also revealed that antibodies produced by several anti-YaYc subclones recognized the Yc subunit, but not the Ya subunit of the antigen which was used for the immunization of the mice. However, these monoclonal antibodies did bind the Ya subunit of ligandin. These results indicate that the Ya subunits of GSH S-transferase B and of ligandin do share at least one common determinant. However, these two Ya subunits are structurally distinct as evidenced by their differences in binding by monoclonal anti-YaYc antibodies.     

Studies of the relationship between the catalytic activity and binding of non-substrate ligands by the glutathione S-transferases.

The dimeric enzyme glutathione S-transferase B is composed of two dissimilar subunits, referred to as Ya and Yc. Transferase B (YaYc) and two other transferases that are homodimers of the individual Ya and Yc subunits were purified from rat liver. Inhibition of these three enzymes by Indocyanine Green, biliverdin and several bile acids was investigated at different values of pH (range 6.0-8.0). Indocyanine Green, biliverdin and chenodeoxycholate were found to be effective inhibitors of transferases YaYc and YcYc at low (pH 6.0) but not high (pH 8.0) values of pH. Between these extremes of pH intermediate degrees of inhibition were observed. Cholate and taurochenodeoxycholate, however, were ineffective inhibitors of transferase YcYc at all values of pH. The observed differences in bile acids appeared to be due, in part, to differences in their state of ionization. In contrast with the above results, transferase YaYa was inhibited by at least 80% by the non-substrate ligands at all values of pH. These effects of pH on the three transferases could not be accounted for by pH-induced changes in the enzyme's affinity for the inhibitor. Thus those glutathione S-transferases that contain the Yc subunit are able to act simultaneously as both enzymes and binding proteins. In addition to enzyme structure, the state of ionization of the non-substrate ligands may also influence whether the transferases can perform both functions simultaneously.     

Newly identified bile acid binders in rat liver cytosol. Purification and comparison with glutathione S-transferases

Gel filtration of male rat liver cytosol preincubated with radiolabeled lithocholic, chenodeoxycholic, and glycochenodeoxycholic acids, and taurocholic acid revealed two major peaks of radioactivity, one co-eluting with the glutathione S-transferases and the other with a separate fraction, respectively. Chromatofocusing of the pooled fractions containing the new bile acid binding activity resulted in a separation of bile acid binding from the previously described organic anion binding activity in this fraction. Two binding peaks for lithocholic acid (pI 5.6, Binder I, and pI 5.5, Binder II) were identified on chromatofocusing and were further purified to apparent homogeneity by hydroxyapatite chromatography. The two Binders were monomers having identical molecular weight (33,000) and similar amino acid compositions. Bile acid binding to purified Binders I and II and glutathione S-transferases A, B, and C was studied by inhibition of the fluorescence of bound 1-anilino-8-naphthalenesulfonate (ANS). Confirmatory experiments using equilibrium dialysis produced comparable results. Glutathione S-transferase B had greater affinity for bile acids than transferases A or C. Binder II, which had greater affinity than Binder I for most bile acids, had greater affinity for chenodeoxycholic acid than transferase B but comparable or lower affinities for the other bile acids. All bile acids studied diminished ANS fluorescence with Binder II. Taurocholic and cholic acids increased ANS fluorescence with Binder I without affecting KANS, whereas lithocholic and chenodeoxycholic acids diminished ANS fluorescence with Binder I. In summary, we have identified and isolated two proteins (Binders I and II) which, along with glutathione S-transferase B, are the major hepatic cytosol bile acid binding proteins; these proteins have overlapping but distinct specificities for various bile acids.     

Evidence for a common high affinity binding site on glutathione S-transferase B for lithocholic acid and bilirubin

Binding of lithocholic acid, bilirubin, and gossypol to glutathione S-transferase B (ligandin or transferase YaYc) was compared using four methods. Tryptophan quenching revealed a single high affinity site for bilirubin and gossypol but could not be used for lithocholic acid. Both displacement of the fluorescent probe, 1-anilino-8-naphthalenesulfonate, and spectral changes induced by bilirubin binding demonstrated a common high affinity site for which all three ligands compete. Similar results were obtained by equilibrium dialysis. The dissociation constants for the binding of both bilirubin and lithocholic acid were comparable with the various methods (range 0.2-0.7 microM). Thus, lithocholic acid and bilirubin share a high affinity binding site on gluthathione S-transferase B that appears to be separate from the binding site for substrates.     

Lithocholate binding by Y and Y' proteins in bovine small intestine.

Cytosolic proteins may play an important role in the intracellular transport of bile acids in enterocytes. The lithocholate binding properties of cytosolic protein from bovine small intestine were studied. Lithocholate binding was observed in the Y (45-50 kDa), Y' (30-35 kDa), and Z fractions (10-15 kDa) following gel filtration of cytosol. A Y protein with glutathione S-transferase activity (46 kDa) was purified by S-octyl-glutathione affinity chromatography and chromatofocusing (eluted at pH 7.5) of the Y fraction. Two Y' bile acid binding proteins with dihydrodiol dehydrogenase activity were partially purified from the Y' fraction by chromatofocusing and hydroxyapatite-HPLC. The lithocholate binding affinity of Y' protein (Kd < 0.35 microM) was higher than that of Y protein (Kd = 2 microM) and was comparable to that of Z protein (Kd = 0.2 microM). The binding affinity of Y protein was higher for bilirubin (Kd = 2.5 microM) than that for BSP (Kd = 200 microM). This was comparable to the binding affinity of bovine hepatic Y protein. These data indicate that Y' and Z proteins participate in the intracellular transport of bile acids from the brush border to the basolateral pole in enterocytes.     

Covalent labeling of the nonsubstrate ligand-binding site of glutathione S-transferases with bilirubin-Woodward's reagent K

The dimeric enzyme glutathione S-transferase B is composed of two dissimilar subunits, referred to as Ya and Yc. Transferase YaYc and the YaYa homodimer were purified from rat liver cytosol. An enol ester derivative of bilirubin (bilirubin-Woodward's reagent K) was prepared and used to label covalently the nonsubstrate ligand-binding site on these two proteins. There was a linear relationship between the amount of bilirubin-Woodward's reagent K added to the reaction mixture and the amount of labeling achieved up to a ratio of 2:1 (bilirubin-Woodward's reagent K: protein-YaYc). A maximum of 0.87 mol of label bound per mol of transferase YaYc. At higher molar ratios, the label appeared to also be binding at a second site on the enzyme. The label blocked the nonsubstrate ligand-binding site of the two transferases but not the catalytic site. The divalent reagent was shown to label equally the Ya and Yc subunits of transferase YaYc, suggesting that the single high affinity bilirubin-binding site present on this protein is formed by an interaction between the subunits rather than residing on a specific subunit. At low ratios of label to protein, bilirubin-Woodward's reagent K appears to label specifically the nonsubstrate ligand-binding site of two forms of glutathione S-transferase, and use of this label should allow for the localization of the nonsubstrate ligand-binding site in the primary amino acid sequence of the Ya and Yc subunits.     

Localization of a portion of the active site of two rat liver glutathione S-transferases using a photoaffinity label

The glutathione S-transferases are a family of dimeric enzymes that catalyze the reaction between GSH and a variety of electrophiles. Two closely related isozymes, referred to as YaYa and YcYc, were purified from rat liver. A radiolabeled azido derivative of glutathione (S-(p-azidophenacyl)[3H]glutathione) was prepared and used to label covalently the active site of the above two glutathione S-transferases. The noncovalently bound affinity label was a competitive inhibitor of glutathione S-transferase YaYa toward both 1-chloro-2,4-dinitrobenzene and GSH. The covalently labeled enzymes no longer bound to a GSH-affinity column, and covalent labeling was reduced in the presence of GSH and S-(dinitrophenyl)glutathione. These results suggest that the affinity label was binding at the active site. The covalently labeled enzymes were digested with trypsin, and the labeled peptides were purified by HPLC and then sequenced. A single-labeled peptide was identified in the tryptic digest of the YaYa isozyme, whereas two labeled peptides were present in the tryptic digest of YcYc. The Ya peptide sequence was identical with the published deduced sequence of amino acids between residues 212 and 218 and the sequences of the two peptides purified from Yc were identical with the deduced sequence of amino acids between 91 and 110 and 206 and 218. Hence, the Ya peptide and the smaller peptide purified from Yc came from the same region of the Ya and Yc subunits. This common region and a second region of the Yc subunit appear to form a portion of the active site of these two forms of glutathione S-transferase.     

Effect of subunit interactions on enzymatic activity of glutathione S-transferases: a radiation inactivation study.

The glutathione S-transferases are a family of dimeric enzymes. Three isozymes from the alpha family, termed YaYa, YaYc, and YcYc, and three from the mu family, termed Yb1Yb1, Yb1Yb2, and Yb2Yb2, were purified from rat liver. Binding studies were performed by equilibrium dialysis using a radiolabeled product, S(-)[14C](dinitrophenyl)glutathione. Each isozyme contained two independent binding sites which had equal affinity for the ligand. The presence of two independent active sites per enzyme dimer suggests that each subunit contains a complete active site. This conclusion was examined further using radiation inactivation which also allowed for assessment of the importance of subunit interactions in catalytic activity. The activity target size of YaYa (47 kDa) was significantly larger than the protein monomer target size (31 kDa); similarly the activity target size of YaYc was that of the dimer (54 kDa). In contrast, the activity target sizes of Yb1Yb1 and Yb2Yb2 were the same, being 35 and 29 kDa, respectively, and the protein monomer target size of Yb1Yb1 also was similar, being 32 kDa. These data indicate that interactions between subunits are critical for the maintenance of enzymatic activity of alpha class enzymes whereas each subunit of the two mu class proteins is capable of independent catalytic activity.     

Comparison of the effects of bile acids and GSH on the fluorescence of bound 1-anilino-8-naphthalene sulfonate and the enzymatic activity of cationic and neutral human hepatic GSH S-transferases

Three cationic (C1, C2, A1) and a neutral (N1) glutathione (GSH) S-transferase were purified to homogeneity from human liver, as we have previously reported. GSH had no effect on the fluorescence of 1-anilino-8-naphthalene sulfonate (ANS) bound by transferase C1 and N1, but markedly enhanced the fluorescence with C2 and A1 without changing the affinity for ANS. This effect of GSH was saturable and with C2 was intermediate between A1 and C1. Bile acids inhibited the fluorescence of ANS bound to C1 and C2. GSH in the presence of bile acids further decreased the fluorescence of ANS bound to C1 and increased the fluorescence with C2. Transferase A1 showed decreased fluorescence in the presence of lithocholic acid and increased fluorescence in the presence of cholic acid; both changes were reversed by GSH. Transferase N1 showed increased fluorescence of bound ANS in the presence of various bile acids and this effect was diminished in the presence of GSH. Enzyme activity of the transferase was inhibited by bile acids with the exception of transferase A1. All the proteins bound lithocholic acid. The inhibition of C1 and N1 was greater at pH 6.5 than 7.4 and the order of addition of substrates and inhibitor made no difference.     

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

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

A novel binding site for bile acids on human serum albumin

Binding sites of bile acids on human serum albumin were studied using various probes: dansylsarcosine (site I probe), 7-anilinocoumarin-4-acetic acid (ACAA, site II probe), 5-dimethylaminonaphthelene-1-sulfonamide (DNSA, site III probe), cis-parinaric acid (probe for fatty acid binding site) and bilirubin. Bile acids competitively inhibited the binding of dansylsarcosine to human serum album whereas bile acids enhanced the binding of ACAA, DNSA, cis-parinaric acid and bilirubin. Considering the concentrations of bile acids required to inhibit the binding of dansylsarcosine to human serum albumin, the secondary binding site of bile acids may correspond to site I. Dissociation constants (K_d) of the primary binding sites of lithocholic and chenodeoxycholic acid to human serum albumin were approximately 0.2 and 4 μM, respectively, which was measured by equilibrium dialysis at 37° C. All the bile acids and their sulfates and glucuronides inhibited the binding of chenodeoxycholic acid to human serum albumin. Lithocholic and chenodeoxycholic acid and their sulfates and glucuronides exhibited more inhibition than cholic acid and its conjugates. In conclusion, bile acids may bind to a novel binding site on human serum albumin.     

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.     

Glutathione-protein mixed disulfide decreases the affinity of rat liver fatty acid-binding protein for unsaturated fatty acid

.16 +/- 0.062% of the fatty acid-binding protein purified from 50 mM N-ethylmaleimide-treated rat liver (L-FABP) was determined as a form S-thiolated by glutathione (L-FABP-SSG). L-FABP-SSG, which was prepared in vitro through thiol-disulfide exchange reaction, showed more acidic pI (approximately 5.0) than the pI (approximately 7.0) of reduced L-FABP. S-thiolation of L-FABP by glutathione decreased the affinity of the protein for unsaturated fatty acids without changing the equimolar maximum binding. The changes in Kd were from 0.63 +/- 0.054 microM to 1.03 +/- 0.14 microM for oleic acid, from 0.63 +/- 0.028 microM to 0.97 +/- 0.12 microM for linoleic acid and from 0.85 +/- 0.050 microM to 1.45 +/- 0.024 microM for arachidonic acid. This modification did not alter the affinity nor the maximum binding for saturated fatty acids, which were determined to be Kd of approximately 1.0 microM for palmitic acid and approximately 0.9 microM for stearic acids, and equimolar maximum binding for both fatty acids. The binding affinity of L-FABP for unsaturated fatty acid may be regulated by redox state of the liver.     

Intestinal microflora and bile acids. Effect of bile acids on the distribution of microflora and bile acid in the digestive tract of the rat

The population levels of intestinal microflora and bile acid composition in the digestive tract were examined in rats fed bile acids to determine the relationships between gastrointestinal microflora and the host. The population level of Bacteroides was increased in the ceca of rats fed cholic acid or deoxycholic acid. In the ileum, the concentration of conjugated bile acid in rats fed cholesterol, cholic acid, hyodeoxycholic acid or lithocholic acid was higher than that in control rats, and was very low in ceca and feces of all the rats. The concentration of total free bile acid was much higher in the ceca than in the ilea of rats fed hyodeoxycholic acid or lithocholic acid. Cholic acid and deoxycholic acid were found in the ilea, ceca and feces of the cholic acid-fed rats. In the deoxycholic acid-fed rats, cholic acid was localized in the ileum. 7-Ketodeoxycholic acid was also found in the ceca of the cholic acid-fed rats. 12-Ketolithocholic acid was found in the feces of rats fed cholic acid or deoxycholic acid. 3-Ketocholanic acid was found in some samples from the lithocholic acid-fed rats. Therefore, some kinds of bile acids influence the population levels of gastrointestinal microflora and bile acid composition in the intestine.     

Hydroxylation, conjugation and sulfation of bile acids in primary monolayer cultures of rat hepatocytes

Hydroxylation of lithocholic, chenodeoxycholic, deoxycholic and cholic acids was studied in monolayers of rat hepatocytes cultured for 76 h. The majority of added lithocholic and chenodeoxycholic acids was metabolized to beta-muricholic acid (56-76%). A small part of these bile acids (9%), however, and a considerable amount of deoxycholic and cholic acids (21%) were converted into metabolites more polar than cholic acid in the first culture period. Formation of these compounds decreased during the last day of culture. Bile acids synthesized after addition of [4-14C]-cholesterol were almost entirely (97%) sulfated and/or conjugated, predominantly with taurine (54-66%), during culture. Sulfated bile acids were mainly composed of free bile acids. The ability of hepatocytes to sulfurylate bile acids declined with culture age. Thus, rat hepatocytes in primary monolayer culture are capable to sulfurylate bile acids and to hydroxylate trihydroxylated bile acids, suggesting formation of polyhydroxylated metabolites.     

Human liver steroid sulphotransferase sulphates bile acids.

The sulphation of bile acids is an important pathway for the detoxification and elimination of bile acids during cholestatic liver disease. A dehydroepiandrosterone (DHEA) sulphotransferase has been purified from male and female human liver cytosol using DEAE-Sepharose CL-6B and adenosine 3',5'-diphosphate-agarose affinity chromatography [Falany, Vazquez & Kalb (1989) Biochem. J. 260, 641-646]. Results in the present paper show that the DHEA sulphotransferase, purified to homogeneity, is also reactive towards bile acids, including lithocholic acid and 6-hydroxylated bile acids, as well as 3-hydroxylated short-chain bile acids. The highest activity towards bile acids was observed with lithocholic acid (54.3 +/- 3.6 nmol/min per mg of protein); of the substrates tested, the lowest activity was detected with hyodeoxycholic acid (4.2 +/- 0.01 nmol/min per mg of protein). The apparent Km values for the enzyme are 1.5 +/- 0.31 microM for lithocholic acid and 4.2 +/- 0.73 microM for taurolithocholic acid. Lithocholic acid also competitively inhibits DHEA sulphation by the purified sulphotransferase (Ki 1.4 microM). No evidence was found for the formation of bile acid sulphates by sulphotransferases different from the DHEA sulphotransferase during purification work. The above results suggest that a single steroid sulphotransferase with broad specificity encompassing neutral steroids and bile acids exists in human liver.     

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.     

Identification of bile acid S-acyl glutathione conjugates in rat bile by liquid chromatography/electrospray ionization–linear ion trap mass spectrometry

Acyl-adenylates and acyl-CoA thioesters of bile acids (BAs) are reactive acyl-linked metabolites that have been shown to acylate the thiol group of glutathione (GSH); the reaction is catalyzed by glutathione S-transferase (GST) and the product is a thioester-linked BA-GSH conjugate. Such GSH conjugates are present in bile in lithocholic acid and ursodeoxycholic acid dosed-rats. To determine whether such novel BA-GSH conjugates are present in the bile of normal rats, we first synthesized the GSH conjugates of the major and minor biliary BAs of the rat and defined their MS and proton NMR properties. We then analyzed the BA-GSH composition in the bile of anesthetized biliary fistula rats by means of liquid chromatographic separation and electrospray ionization–linear ion trap mass spectrometric detection in negative- and positive-ion scan modes, monitoring characteristic transitions of the analytes. GSH conjugates of cholic, ω-muricholic, hyodeoxycholic, deoxycholic, 12-oxolithocholic, and lithocholic acids were present with concentrations in the range of 1.4–2.8 nmol/ml, some four orders of magnitude less than those of natural BA N-acyl amidates. Our results indicate that BA-GSH conjugates are formed and excreted in bile in the healthy rat, although this novel mode of BA conjugation is a very minor pathway.