Immunological and sequence interrelationships between multiple human liver and rat glutathione S-transferases

The 13 forms of human liver glutathione S-transferases (GST) (Vander Jagt, D. L., Hunsaker, L. A., Garcia, K. B., and Royer, R. E. (1985) J. Biol. Chem. 260, 11603-11610) are composed of subunits in two electrophoretic mobility groups: Mr = 26,000 (Ha) and Mr = 27,500 (Hb). Preparations purified from the S-hexyl GSH-linked Sepharose 4B affinity column revealed three additional peptides at Mr = 30,800, Mr = 31,200, and Mr = 32,200. Immunoprecipitation of human liver poly(A) RNAs in vitro translation products revealed three classes of GST subunits and related peptides at Mr = 26,000, Mr = 27,500, and Mr = 31,000. The Mr = 26,000 species (Ha) can be precipitated with antisera against a variety of rat liver GSTs containing Ya, Yb, and Yc subunits, whereas the Mr = 27,500 species (Hb) can be immunoprecipitated most efficiently by antiserum against the anionic isozymes as well as a second Yb-containing isozyme (peak V) from the rat liver. The Mr = 31,000 band can be immunoprecipitated by antisera preparations against sheep liver, rat liver, and rat testis isozymes. Human liver GSTs do not have any subunits of the rat liver Yc mobility. Antiserum against the human liver GSTs did not cross-react with the Yc subunits of rat livers or brains in immunoblotting experiments. The human liver GST cDNA clone, pGTH1, selected human liver poly(A) RNAs for the Ha subunit(s) in the hybrid-selected in vitro translation experiments. Southern blot hybridization results revealed cross-hybridization of pGTH1 with the Ya, Yb, and Yc subunit cDNA clones of rat liver GSTs. This sequence homology was substantiated further in that immobilized pGTH1 DNA selected rat liver poly(A) RNAs for the Ya, Yb, and Yc subunits with different efficiency as assayed by in vitro translation and immunoprecipitation. Therefore, we have demonstrated convincingly that sequence homology as well as immunological cross-reactivity exist between GST subunits from several rat tissues and the human liver. Also, the multiple forms of human liver GSTs are most likely encoded by a minimum of three different classes of mRNAs. These results suggest a genetic basis for the subunit heterogeneity of human liver GSTs.     

Cloning and sequence analysis of a cDNA for a rat liver glutathione S-transferase Yb subunit.

We have isolated a Yb-subunit cDNA clone from a GSH S-transferase (GST) cDNA library made from rat liver polysomal poly(A) RNAs. Sequence analysis of one of these cDNA, pGTR200, revealed an open reading frame of 218 amino acids of Mr = 25,915. The deduced sequence is in agreement with the 19 NH2-terminal residues for GST-A. The sequence of pGTR200 differs from another Yb cDNA, pGTA/C44 by four nucleotides and two amino acids in the coding region, thus revealing sequence microheterogeneity. The cDNA insert in pGTR200 also contains 36 nucleotides in the 5' noncoding region and a complete 3' noncoding region. The Yb subunit cDNA shares very limited homology with those of the Ya or Yc cDNAs, but has relatively higher sequence homology to the placental subunit Yp clone pGP5. The mRNA of pGTR200 is not expressed abundantly in rat hearts and seminal vesicles. Therefore, the GST subunit sequence of pGTR200 probably represents a basic Yb subunit. Genomic DNA hybridization patterns showed a complexity consistent with having a multigene family for Yb subunits. Comparison of the amino acid sequences of the Ya, Yb, Yc, and Yp subunits revealed significant conservation of amino acids (approximately 29%) throughout the coding sequences. These results indicate that the rat GSTs are products of at least four different genes that may constitute a supergene family.     

Human liver glutathione S-transferases: complete primary sequence of an Ha subunit cDNA

Multiple human liver GSH S-transferases (GST) with overlapping substrate specificities may be essential to their multiple roles in xenobiotics metabolism, drug biotransformation, and protection against peroxidative damage. Human liver GSTs are composed of at least two classes of subunits, Ha (Mr = 26,000) and Hb (Mr = 27,500). Immunological cross-reactivity and nucleic acid hybridization studies revealed a close relationship between the human Ha subunit and rat Ya, Yc subunits and their cDNAs. We have determined the nucleotide sequence of the Ha subunit 1 cDNA, pGTH1. The alignments of its coding sequence with the rat Ya and Yc cDNAs indicate that they are approximately 80% identical base-for-base without any deletion or insertion. Regions of sequence homology (greater than 50%) have also been found between pGTH1 and a corn GST cDNA and rat GST cDNAs of the Yb and Yp subunits. Among the 62 highly conserved amino acid residues of the rat GST supergene family, 56 of them are preserved in the Ha subunit 1 coding sequences. Comparison of amino-acid replacement mutations in these coding sequences revealed that the percentage divergence between the rat Ya and Yc genes is more than that between the Ha and Ya or Ha and Yc genes.     

Preferential over-expression of the class alpha rat Ya2 glutathione S-transferase subunit in livers bearing aflatoxin-induced pre-neoplastic nodules. Comparison of the primary structures of Ya1 and Ya2 with cloned class alpha glutathione S-transferase cDNA sequences.

Normal rat liver expresses Ya (Mr 25,500), Yc (Mr 27,500) and Yk (Mr 25,000) Class Alpha glutathione S-transferase (GST) subunits. The Ya-type subunit can be resolved into two separate polypeptides, designated Ya1 and Ya2, by reverse-phase h.p.l.c. In rat livers that possess aflatoxin B1-induced pre-neoplastic nodules, a marked increase is observed in the expression of Ya1, Ya2, Yc and Yk; of these subunits, Ya2 exhibited the greatest increase in concentration. The Ya1 and Ya2 subunits isolated from nodule-bearing livers were cleaved with CNBr, and the purified peptides were subjected to automated amino-acid-sequence analysis. Differences in the primary structures of the two Ya GST subunits were found at positions 31, 34, 107 and 117. These data demonstrate that Ya1 and Ya2 are distinct polypeptides and are the products of separate genes. The amino acid sequences obtained from Ya1 and Ya2 were compared with the cloned cDNAs pGTB 38 [Pickett, Telakowski-Hopkins, Ding, Argenbright & Lu (1984) J. Biol. Chem. 259, 4112-4115] and pGTR 261 [Lai, Li, Weiss, Reddy & Tu (1984) J. Biol. Chem. 259, 5182-5188], which encode rat Ya-type subunits. From these comparisons it appears probable that Ya1 represents the GST subunit encoded by pGTR 261, whereas Ya2 represents the subunit encoded by pGTB 38. It is likely that the over-expression of Ya1 and Ya2 in nodule-bearing livers is of major significance in the acquired resistance of nodules to aflatoxin B1, since previous work [Coles, Meyer, Ketterer, Stanton & Garner (1985) Carcinogenesis 6, 693-697] has shown that the Ya-type GST subunit has high activity towards aflatoxin B1 8,9-epoxide.     

Use of immuno-blot techniques to discriminate between the glutathione S-transferase Yf, Yk, Ya, Yn/Yb and Yc subunits and to study their distribution in extrahepatic tissues. Evidence for three immunochemically distinct groups of transferase in the rat.

The glutathione S-transferases are dimeric enzymes whose subunits can be defined by their mobility during sodium dodecyl sulphate/polyacrylamide-gel electrophoresis as Yf (Mr 24,500), Yk (Mr 25,000), Ya (Mr 25,500), Yn (Mr 26,500), Yb1 (Mr 27,000), Yb2 (Mr 27,000) and Yc (Mr 28,500) [Hayes (1986) Biochem. J. 233, 789-798]. Antisera were raised against each of these subunits and their specificities assessed by immuno-blotting. The transferases in extrahepatic tissues were purified by using, sequentially, S-hexylglutathione and glutathione affinity chromatography. Immune-blotting was employed to identify individual transferase polypeptides in the enzyme pools from various organs. The immuno-blots showed marked tissue-specific expression of transferase subunits. In contrast with other subunits, the Yk subunit showed poor affinity for S-hexylglutathione-Sepharose 6B in all tissues examined, and subsequent use of glutathione and glutathione affinity chromatography. Immuno-blotting was employed to identify a new cytosolic polypeptide, or polypeptides, immunochemically related to the Yk subunit but with an electrophoretic mobility similar to that of the Yc subunit; high concentrations of the new polypeptide(s) are present in colon, an organ that lacks Yc.     

Purification and subunit-structural and immunological characterization of five glutathione S-transferases in human liver, and the acidic form as a hepatic tumor marker

Five glutathione S-transferase (GST, EC 2.5.1.18) forms were purified from human liver by S-hexylglutathione affinity chromatography followed by chromatofocusing, and their subunit structures and immunological relationships to rat liver glutathione S-transferase forms were investigated. They were tentatively named GSTs I, II, III, IV and V in order of decreasing apparent isoelectric points (pI) on chromatofocusing. Their subunit molecular weights assessed on SDS-polyacrylamide gel electrophoresis were 27 (Mr X 10(-3)), 27, 27.7,27 and 26, respectively, (26, 26, 27, 26, and 24.5 on the assumption of rat GST subunit Ya, Yb and Yc as 25, 26.5 and 28, respectively), indicating that all forms are composed of two subunits identical in size. However, it was suggested by gel-isoelectric focusing in the presence of urea that GSTs I and IV are different homodimers, consisting of Y1 and Y4 subunits, respectively, which are of identical Mr but different pI, while GST II is a heterodimer composed of Y1 and Y4 subunits. This was confirmed by subunit recombination after guanidine hydrochloride treatment. GST III seemed to be identical with GST-mu with regard to Mr and pI. GST V was immunologically identical with the placental GST-pi. On double immunodiffusion or Western blotting using specific antibodies to rat glutathione S-transferases, GST I, II and IV were related to rat GST 1-1 (ligandin), GST III(mu) to rat GST 4-4 (D), and GST V (pi) to rat GST 7-7 (P), respectively. GST V (pi) was increased in hepatic tumors.     

Ligandin heterogeneity : evidence that the two non-identical subunits are the monomers of two distinct proteins.

Purified ligandin (Y-protein) a 46000-dalton protein, has been shown to consist of two subunit species (mol. wts. 22 000 and 24 000) on discontinuous polyacrylamide gel electrophoresis in sodium dodecyl sulphate. This technique was used to define further the nature of these subunits. The Y sulphobromophthalein-binding fraction of rat hepatic cytosol was shown to contain three major subunit bands designated subunit Ya, subunit Yb and subunit Yc in ascending order of size. Purified ligandin was found to comprise Ya and Yc subunit species, and also gave two bands on isoelectric focusing. The two subunit species in purified ligandin were partially separated by an additional purification step. Antiserum to ligandin reacted mono-specifically with the purified protein, as well as hepatic, renal and small intestinal mucosa cytosol, but gave lines of identity and partial identity with cytosol from testis, ovary and adrenal gland. The Y fraction of testis was found to contain only Yb and Yc species, while all three major bands were found in liver, kidney and small intestinal mucosa. Phenobarbital treatment increased the concentration of Ya and Yb in the liver, but had little effect on Yc. These findings suggest that the Ya and Yc ligandin subunits are the monomers of two proteins: YaYa and YcYc.     

Anomalous electrophoretic behaviour of the glutathione S-transferase Ya and Yk subunits isolated from man and rodents. A potential pitfall for nomenclature.

GSH S-transferases are dimeric enzymes. The subunits in the rat are resolved into six types, designated Yf, Yk, Ya, Yn, Yb and Yc, by discontinuous SDS/polyacrylamide-gel electrophoresis [Hayes (1986) Biochem. J. 233, 789-798]. The relative electrophoretic mobility of the Ya and Yk subunits is dependent on the amount of cross-linker (NN'-methylenebisacrylamide) in the resolving gel. At low degrees of cross-linking, CBis 0.6% (w/w), the Yk and Ya subunits possess a faster anodal mobility than do the Yf, Yn, Yb and Yc subunits (i.e. order of mobility Yk greater than Ya greater than Yf greater than Yn greater than Yb greater than Yc), whereas at higher degrees of cross-linking, CBis 5.0% (w/w), Yf subunits possess the fastest mobility (i.e. order of mobility Yf greater than Yk greater than or equal to Yn greater than Yb greater than or equal to Ya greater than Yc). Resolving gels that contain low concentrations of cross-linker [CBis 0.6% (w/w)] allow the resolution of a hitherto unrecognized polypeptide that is isolated by S-hexyl-GSH-Sepharose affinity chromatography. This new polypeptide, which we have designated Yb, is normally obscured by the main Yb band in resolving gels that comprise concentrations of cross-linker of at least CBis 1.6% (w/w). The Ya- and Yb-type subunits in guinea pig, mouse, hamster and man were identified by immuno-blotting and their apparent Mr values in different electrophoresis systems were determined. The Ya subunits in all species studied possess a variable cross-linker-dependent mobility during electrophoresis. Since the transferase subunits are currently classified according to their mobilities during SDS/polyacrylamide-gel electrophoresis, it is apparent that the variable electrophoretic behaviour of the Ya and Yk subunits may lead to the mis-identification of enzymes.     

Rat liver glutathione S-transferases. Construction of a cDNA clone complementary to a Yc mRNA and prediction of the complete amino acid sequence of a Yc subunit

Using polysomal immunoselected rat liver glutathione S-transferase mRNAs, we have constructed cDNA clones using DNA polymerase I, RNase H, and Escherichia coli ligase (NAD+)-mediated second strand cDNA synthesis as described by Gubler and Hoffman (Gubler, U., and Hoffman, B. S. (1983) Gene 25, 263-269). Recombinant clone, pGTB42, contained a cDNA insert of 900 base pairs whose 3' end showed specificity for the Yc mRNA in hybrid-select translation experiments. The nucleotide sequence of pGTB42 has been determined, and the complete amino acid sequence of a Yc subunit has been deduced. The cDNA clone contains an open reading frame of 663 nucleotides encoding a polypeptide comprising 221 amino acids with a molecular weight of 25,322. The NH2-terminal sequence deduced from pGTB42 is in agreement with the first 39 amino acids determined for a Ya-Yc heterodimer by conventional protein-sequencing techniques. A comparison of the nucleotide sequence of pGTB42 with the sequence of a Ya clone, pGTB38, described previously by our laboratory (Pickett, C. B., Telakowski-Hopkins, C. A., Ding, G. J.-F., Argenbright, L., and Lu, A.Y.H. (1984) J. Biol. Chem. 259, 5182-5188) reveals a sequence homology of 66% over the same regions of both clones; however, the 5'- and 3'-untranslated regions of the Ya and Yc mRNAs are totally divergent in their sequences. The overall amino acid sequence homology between the Ya and Yc subunits is 68%, however, the NH2-terminal domain is more highly conserved than the middle or carboxyl-terminal domains. Our data suggest that the Ya and Yc subunits of the rat liver glutathione S-transferases are products of two different mRNAs which are derived from two related yet different genes.     

Rat liver glutathione S-transferases. Nucleotide sequence analysis of a Yb1 cDNA clone and prediction of the complete amino acid sequence of the Yb1 subunit

We have constructed a nearly full length cDNA clone, pGTA/C44, complementary to the rat liver glutathione S-transferase Yb1 mRNA. The nucleotide sequence of pGTA/C44 has been determined, and the complete amino acid sequence of the Yb1 subunit has been deduced. The cDNA clone contains an open reading frame of 654 nucleotides encoding a polypeptide comprising 218 amino acids with Mr = 25,919. The NH2-terminal sequence deduced from DNA sequence analysis of pGTA/C44 is in agreement with the first 19 amino acids determined for purified glutathione S-transferase A, a Yb1 homodimer, by Frey et al. (Frey, A. B., Friedberg, T., Oesch, F., and Kreibich, G. (1983) J. Biol. Chem. 258, 11321-11325). The DNA sequence of pGTA/C44 shares significant sequence homology with a cDNA clone, pGT55, which is complementary to a mouse liver glutathione S-transferase (Pearson, W. R., Windle, J. J., Morrow, J. F., Benson, A. M., and Talalay, P. (1983) J. Biol. Chem. 258, 2052-2062). We have also determined 37 nucleotides of the 5'-untranslated region and 348 nucleotides of the 3'-untranslated region of the Yb1 mRNA. The Yb1 mRNA and subunit do not share any sequence homology with the rat liver glutathione S-transferase Ya or Yc mRNAs or their corresponding subunits. These data provide the first direct evidence that the Yb1 subunit is derived from a gene or gene family which is distinct from the Ya-Yc gene family.     

Comparative studies on the isoenzymes of glutathione S-transferase of rat brain and other tissues

Six forms of glutathione S-transferase (GST) designated as GST 9.3, GST 7.5, GST 6.6, GST 6.1, GST 5.7 and GST 4.9 have been purified to homogeneity from rat brain. All GST isoenzymes of rat brain are apparent homodimers of one of the three type subunits, Ya, Yb, or Yc. More than 60% of total GST activity of rat brain GST activity is associated with the isoenzymes containing only the Yb type of subunits. In these respects brain GST isoenzymes differ from those of lung and liver. The Ya, Yb, and Yc type subunits of brain GST are immunologically similar to the corresponding subunits of liver and lung GST. The isoelectric points and kinetic properties of the Yb type subunit dimers in brain are strikingly different from those of the Yb type dimers present among liver GST isoenzymes indicating subtle differences between these subunits of brain and liver.     

A new class of rat glutathione S-transferase Yrs-Yrs inactivating reactive sulfate esters as metabolites of carcinogenic arylmethanols

A glutathione (GSH) S-transferase (GST), catalyzing the inactivation of reactive sulfate esters as metabolites of carcinogenic arylmethanols, was isolated from the male Sprague-Dawley rat liver cytosol and purified to homogeneity in 12% yield with a purification factor of 901-fold. The purified GST was a homo-dimeric enzyme protein with subunit Mr 26,000 and pI 7.9 and designated as Yrs-Yrs because of its enzyme activity toward "reactive sulfate esters." GST Yrs-Yrs could neither be retained on the S-hexylglutathione gel column nor showed any activity toward 1,2-dichloro-4-nitrobenzene, 4-nitrobenzyl chloride, and 1,2-epoxy-3-(4'-nitrophenoxy)propane. 1-Chloro-2,4-dinitro-benzene was a very poor substrate for this GST. 1-Menaphthyl sulfate was the best substrate for GST Yrs-Yrs among the examined mutagenic arylmethyl sulfates. The enzyme had higher activities toward ethacrynic acid and cumene hydroperoxide. N-terminal amino acid sequence of subunit Yrs, analyzed up to the 25th amino acid, had no homology with any of the known class alpha, mu, and pi enzymes of the Sprague-Dawley rat. Anti-Yrs-IgG raised against GST Yrs-Yrs showed no cross-reactivity with any of subunits Ya, Yc, Yb1, Yb2, and Yp. Anti-IgGs raised against Ya, Yc, Yb1, Yb2, and Yp also showed no cross-reactivity with GST Yrs-Yrs. The purified enzyme proved to differ evidently from the 12 known cytosolic GSTs in various tissues of the rat in all respects. Immunoblot analysis of various tissue cytosols of the male rat indicated that apparent concentrations of the GST Yrs-Yrs protein were in order of liver greater than testis greater than adrenal greater than kidney greater than lung greater than brain greater than skeletal muscle congruent to heart congruent to small intestine congruent to spleen congruent to skin congruent to 0.     

Purification and characterization of glutathione S-transferases P, S and N. Isolation from rat liver of Yb1 Yn protein, the existence of which was predicted by subunit hybridization in vitro.

The glutathione S-transferases are dimeric proteins and comprise subunits of Mr 25 500 (Ya), 26 500 (Yn), 27 000 (Yb1 and Yb2) and 28 500 (Yc). Enzymes containing Ya and/or Yc subunits have been isolated as have forms containing binary combinations of Yn, Yb1 and Yb2 subunits. To date only one enzyme, transferase S, has been described that is a YbYn heterodimer [Hayes & Chalmers (1983) Biochem. J. 215, 581-588]; the identity of the Yb monomer found in transferase S has not been reported previously. The identification and isolation of a YnYn dimer (transferase N) from rat testis is now described. This has enabled structural and functional comparisons to be made between Yb1, Yb2 and Yn monomers. Reversible dissociation experiments between the YnYn and Yb1Yb1 homodimers and between the YnYn and Yb2Yb2 homodimers demonstrated that Yn monomers can hybridize with both Yb1 and Yb2 monomers. Reversible dissociation of transferases N and C (Yb1Yb2) showed that both Yb1 and Yb2 monomers can hybridize with Yn monomers under competitive conditions. The hydridization data suggest that transferase S represents the Yb2Yn subunit combination. A knowledge of the elution position from chromatofocusing columns of the Yb1Yn hybrid that was formed in vitro enabled a purification scheme to be devised for an enzyme from rat liver (transferase P) believed to consist of Yb1Yn subunits. A comparison of the chromatographic behaviour of the YnYn, Yb1Yb1 and Yb2Yb2 dimers on chromatofocusing and hydroxyapatite columns with the behaviour of transferases P and S on the same matrices suggests these two enzymes may be identified as the Yb1Yn and Yb2Yn dimers respectively. The catalytic activities and the inhibitory effects of non-substrate ligands on transferases P and S are significantly different and again suggest they comprise Yb1 and Yn subunits and Yb2 and Yn subunits respectively; transferase P exhibits a 6-fold higher specific activity for 1,2-dichloro-4-nitrobenzene than does transferase S, whereas, conversely, transferase S possesses a 9-fold higher specific activity for trans-4-phenylbut-3-en-2-one than does transferase P. The quaternary structure of transferases P and S was verified by using peptide mapping and 'Western blotting' techniques.     

Specificity of the glutathione S-transferases in the conversion of leukotriene A4 to leukotriene C4

We have synthesized the 5,6-LTA4, 8,9-LTA4, and 14,15-LTA4 as methyl esters by an improved biomimetic method with yields as high as 70-80%. We have investigated the catalytic efficiency of the purified cytosolic glutathione S-transferase (GST) isozymes from rat liver in the conversion of these leukotriene epoxides to their corresponding LTC4 methyl esters. Among various rat liver GST isozymes, the anionic isozyme, a homodimer of Yb subunit, exhibited the highest specific activity. In general, the isozymes containing the Yb subunit showed better activity than the isozymes containing the Ya and/or Yc subunits. Interestingly, all three different LTA4 methyl esters gave comparable specific activities with a given GST isozyme indicating that regiospecificity of GSTs was not the factor in determining their ability to catalyze this reaction. Surprisingly, purified GSTs from sheep lung and seminal vesicles showed little activity toward these leukotriene epoxides, indicating a lack of the counterpart of rat liver anionic GST isozyme in these tissues.     

Expression of glyoxalase, glutathione peroxidase and glutathione S-transferase isoenzymes in different bovine tissues

(1) The tissue-specific expression of various glutathione-dependent enzymes, including glutathione S-transferase (GST), glutathione peroxidase and glyoxalase I, has been studied in bovine adrenals, brain, heart, kidney, liver, lung and spleen. Of the organs studied, liver was found to possess the greatest GST and glyoxalase I activity, and spleen the greatest glutathione peroxidase activity. The adrenals contained large amounts of these glutathione-dependent enzymes, but significant differences were observed between the cortex and medulla. (2) GST and glyoxalase I activity were isolated by S-hexylglutathione affinity chromatography. Glyoxalase I was found in all the organs examined, but GST exhibited marked tissue-specific expression. (3) The alpha, mu and pi classes of GST (i.e., those that comprise respectively Ya/Yc, Yb/Yn and Yf subunits) were all identified in bovine tissues. However, the Ya and Yc subunits of the alpha class GST were not co-ordinately regulated nor were the Yb and Yn subunits of the mu class GST. (4) Bovine Ya subunits (25.5-25.7 kDa) were detected in the adrenal, liver and kidney, but not in brain, heart, lung or spleen. The Yc subunit (26.4 kDa) was expressed in all those organs which expressed the Ya subunit, but was also found in lung. The mu class Yb (27.0 kDa) and Yn (26.1 kDa) subunits were present in all organs; however, brain, lung and spleen contained significantly more Yn than Yb type subunits. The pi class Yf subunit (24.8 kDa) was detected in large amounts in the adrenals, brain, heart, lung and spleen, but not in kidney or liver. (5) Gradient affinity elution of S-hexylglutathione-Sepharose showed that the bovine proteins that bind to this matrix elute in the order Ya/Yc, Yf, Yb/Yn and glyoxalase I. (6) In conclusion, the present investigation has shown that bovine GST are much more complex than previously supposed; Asaoka (J. Biochem. 95 (1984) 685-696) reported the purification of mu class GST but neither alpha nor pi class GST were isolated.     

Inhibition of hepatic and extrahepatic glutathione S-transferases by primary and secondary bile acids.

Glutathione S-transferases are a complex family of dimeric proteins that play a dual role in cellular detoxification; they catalyse the first step in the synthesis of mercapturic acids, and they bind potentially harmful non-substrate ligands. Bile acids are quantitatively the major group of ligands encountered by the glutathione S-transferases. The enzymes from rat liver comprise Yk (Mr 25 000), Ya (Mr 25 500), Yn (Mr 26 500), Yb1, Yb2 (both Mr 27 000) and Yc (Mr 28 500) monomers. Although bile acids inhibited the catalytic activity of all transferases studied, the concentration of a particular bile acid required to produce 50% inhibition (I50) varies considerably. A comparison of the I50 values obtained with lithocholate (monohydroxylated), chenodeoxycholate (dihydroxylated) and cholate (trihydroxylated) showed that, in contrast with all other transferase monomers, the Ya subunit possesses a relatively hydrophobic bile-acid-binding site. The I50 values obtained with lithocholate and lithocholate 3-sulphate showed that only the Ya subunit is inhibited more effectively by lithocholate than by its sulphate ester. Other subunits (Yk, Yn, Yb1 and Yb2) were inhibited more by lithocholate 3-sulphate than by lithocholate, indicating the existence of a significant ionic interaction, in the bile-acid-binding domain, between (an) amino acid residue(s) and the steroid ring A. By contrast, increasing the assay pH from 6.0 to 7.5 decreased the inhibitory effect of all bile acids studied, suggesting that there is little significant ionic interaction between transferase subunits and the carboxy group of bile acids. Under alkaline conditions, low concentrations (sub-micellar) of nonsulphated bile acids activated Yb1, Yb2 and Yc subunits but not Yk, Ya and Yn subunits. The diverse effects of the various bile acids studied on transferase activity enables these ligands to be used to help establish the quaternary structure of individual enzymes. Since these inhibitors can discriminate between transferases that appear to be immunochemically identical (e.g. transferases F and L), bile acids can provide information about the subunit composition of forms that cannot otherwise be distinguished.     

Suppression of glutathione S-transferases in rat seminal vesicles or pituitary glands

We have studied the tissue-specific expression of GSH S-transferases in rat seminal vesicles and pituitary glands by in vitro translation and immunoprecipitation. The major GSH S-transferase subunit expressed in rat seminal vesicles belongs to the Yb mobility class whose expression diminishes when the rats are treated with pentobarbital. The pattern of GSH S-transferase expression in the pituitary gland is very similar to that of the rat brain with Yb size subunit(s) predominant. The Y beta size subunit is also expressed together with the Yc and Y delta subunits. The expression of GSH S-transferases was drastically reduced in pituitary gland poly(A) RNAs from diethylstilbestrol-treated, ovariectomized female rats. Xenobiotics such as phenobarbital, 3-methylcholanthrene, and trans-stilbene oxide induce rat liver GSH S-transferase activities, especially the Ya- and Yb-subunit containing isozymes. Induction of GSH S-transferases by a combination of the three xenobiotics is neither additive nor synergistic, however. Our results clearly demonstrate that GSH S-transferase expression in seminal vesicles and pituitary glands can be suppressed by phenobarbital and diethylstilbestrol, respectively. Our findings suggest that different GSH S-transferase isozymes respond differently to various xenobiotics. Both induction and suppression occur in rats treated with xenobiotics. This notion helps to explain the lack of additive or synergistic induction in rats treated with more than one xenobiotic.