The basic glutathione S-transferases from human livers are products of separate genes

We have characterized a second cDNA sequence, pGTH2, for the human liver glutathione S-transferases Ha subunits. It is 95% homologous base-for-base to the Ha subunit 1 cDNA, pGTH1, except for its longer 3' noncoding sequences. Our results indicate that the multiple basic human liver glutathione S-transferases are products of separate genes. The proposal [Kamisaka, K., Habig, W. H., Ketley, J. N., Arias, I. M., and Jakoby, W. B. (1975) Eur. J. Biochem. 60, 153-161] that deamidation may be a physiologically important process for generating glutathione S-transferases isozyme multiplicity can be all but ruled out.     

Rat liver glutathione S-transferase B: the functional mRNAs specific for the Ya Yc subunits are induced differentially by phenobarbital

Liver poly(A⁺)-RNA isolated from untreated and phenobarbital-treated rats has been translated in the rabbit reticulocyte cell-free system in order to examine the kinetics of induction of the translatable mRNAs encoding each subunit of glutathione S-transferase B. Translatable glutathione S-transferase B mRNA levels were maximally elevated at 16 to 24 h after a single injection of phenobarbital. Interestingly, the functional mRNA specific for the low-molecular-weight subunit was elevated markedly by phenobarbital administration whereas the mRNA specific for the high-molecular-weight subunit was only increased slightly. Our data suggest that different mRNAs direct the synthesis of the two subunits of glutathione S-transferase B and that these two mRNAs are under independent regulation.     

Chromosomal assignments of genes for rat glutathione S-transferase Ya (GSTA1) and Yc subunits (GSTA2).

Chromosomal assignments of genes for rat glutathione S-transferase Ya (GSTA1) and Yc subunits (GSTA2) were performed by Southern blot analyses of somatic cell hybrid DNAs.GSTA1 and GSTA2 were assigned to rat chromosomes 8 and 9, respectively.     

Rat liver glutathione S-transferases. Complete nucleotide sequence of a glutathione S-transferase mRNA and the regulation of the Ya, Yb, and Yc mRNAs by 3-methylcholanthrene and phenobarbital

With the use of cDNA probes reverse transcribed from purified glutathione S-transferase mRNA templates, four cDNA clones complementary to transferase mRNAs have been identified and characterized. Two clones, pGTB38 and pGTB34, have cDNA inserts of approximately 950 and 900 base pairs, respectively, and hybridize to a mRNA(s) whose size is approximately 980 nucleotides. In hybrid-select translation experiments, pGTB38 and pGTB34 select mRNAs specific for the Ya and Yc subunits of rat liver glutathione S-transferases. Clone pGTB33, which harbors a truncated cDNA insert, hybrid-selects only the Ya mRNA. All of the clones, pGTB38, pGTB34, and pGTB33, hybrid-select another mRNA which is specific for a polypeptide with an electrophoretic mobility slightly greater than the Ya subunit. The entire nucleotide sequence of the full length clone, pGTB38, has been determined and the complete amino acid sequence of the corresponding polypeptide has been deduced. The mRNA codes for a protein comprising 222 amino acids with Mr = 25,547. We have also identified a cDNA clone complementary to a Yb mRNA of the rat liver glutathione S-transferases. This clone, pGTA/C36, hybrid-selects only Yb mRNA(s) and hybridizes to a mRNA(s) whose size is approximately 1200 nucleotides. Although the Ya, Yb, and Yc mRNAs are elevated coordinately by phenobarbital and 3-methylcholanthrene, the Ya-Yc mRNAs are induced to a much greater extent compared to the Yb mRNA(s). These data suggest that the mRNAs for each transferase isozyme are regulated independently.     

Two immunologically distinct Yc-type subunits are present in rat lung glutathione S-transferases.

Two types of 25 000-Mr subunits are present in rat lung glutathione S-transferase I (pI 8.8). These subunits, designated Yc and Yc', are immunologically and functionally distinct from each other. The homodimers YcYc (pI 10.4) and Yc'Yc' (pI 7.6) obtained by hybridization in vitro of the two subunits of glutathione S-transferase I (pI 8.8) were isolated and characterized. Results of these studies indicate that only the Yc subunits express glutathione peroxidase activity and cross-react with the antibodies raised against glutathione S-transferase B (YaYc) or rat liver. The Yc' subunits do not express glutathione peroxidase activity and do not cross-react with the antibodies raised against glutathione S-transferase B of rat liver. The amino acid compositions of these two subunits are also different. These two subunits can also be separated by the two-dimensional gel electrophoresis of glutathione S-transferase I (pI 8.8) of rat lung.     

On the multiplicity of rat liver glutathione S-transferases

Rat liver glutathione S-transferases have been purified to apparent electrophoretic homogeneity by S-hexylglutathione-linked Sepharose 6B affinity chromatography and CM-cellulose column chromatography. At least 11 transferase activity peaks can be resolved including five Yb size homodimeric isozymes, two Yc size homodimeric isozymes, one Ya homodimeric isozyme, one Y alpha homodimeric isozyme, and two Ya-Yc heterodimeric isozymes. Distribution of the GSH peroxidase activity among the CM-cellulose column fractions suggests the existence of further multiplicity in this isozyme family. Substrate specificity patterns of the Yb subunit isozymes revealed a possibility that each of the five Yb-containing isozymes is composed of a different homodimeric Yb size subunit composition. Our findings on the increasing multiplicity of glutathione S-transferase isozymes are consistent with the notion that multiple isozymes of overlapping substrate specificities are required to detoxify a multitude of xenobiotics in addition to serving other important physiological functions.     

Subunit composition of rat liver glutathione S-transferases

The plasmid pGTR112 contains partial coding sequences for one of the rat liver glutathione S-transferase subunits. We have used immobilized pGTR112 DNA to select for complementary and homologous liver poly(A)-RNAs under conditions of increasing stringency for hybridization. Each fraction of selected poly(A)-RNAs was assayed by in vitro translation followed by immunoprecipitation. A total of four distinct polypeptides precipitated by antiserum against rat liver glutathione S-transferases were resolved by NaDodSO₄ polyacrylamide gel electrophoresis. They are separated into two pairs according to the sequence homology of their poly(A)-RNAs with the pGTR112 DNA. Purified rat liver glutathione S-transferases can be resolved on gradient NaDodSO₄ polyacrylamide gels into four polypeptides. There should be ten isozymes of different binary combinations from four distinct subunits for the rat liver glutathione S-transferases.     

Comparative effect of the induction of the subunits of rat liver glutathione S-transferases by butylated hydroxytoluene

When butylated hydroxytoluene (BHT) was administered to rats, the smallest subunit Ya (Mr 22,000) of rat liver GSH S-transferases was found to undergo maximum induction. It is suggested that the differential induction of GSH S-transferase activities by BHT towards different substrates may be due to the differences in the induction of the constituent subunits of GSH S-transferases.     

Evidence that glutathione S-transferases B1B1 and B2B2 are the products of separate genes and that their expression in human liver is subject to inter-individual variation. Molecular relationships between the B1 and B2 subunits and other Alpha class glutathione S-transferases.

The Alpha class glutathione S-transferases (GSTs) in human liver are composed of polypeptides of Mr 25,900. These enzymes are dimeric, and two immunochemically distinct subunits, B1 and B2, have been described that combine to form GSTs B1B1, B1B2 and B2B2 [Stockman, Beckett & Hayes (1985) Biochem. J. 227, 457-465]. Gradient affinity elution from GSH-Sepharose has been used to resolve the three Alpha class GSTs, and this method has been applied to demonstrate marked inter-individual differences in the hepatic content of GSTs B1B1, B1B2 and B2B2. The B1 and B2 subunits can be resolved by reverse-phase h.p.l.c., and their elution positions suggest that they are equivalent to the alpha chi and alpha y h.p.l.c. peaks described by Ketterer and his colleagues [Ostlund Farrants, Meyer, Coles, Southan, Aitken, Johnson & Ketterer (1987) Biochem. J. 245, 423-428]. The B1 and B2 subunits have now been cleaved with CNBr and the fragments subjected to automated amino acid sequence analysis. The sequence data show that B1 and B2 subunits do not arise from post-translational modification, as had been previously believed for the hepatic Alpha class GSTs, but are instead the products of separate genes; B1 and B2 subunits were found to contain different amino acid residues at positions 88, 110, 111, 112, 116, 124 and 127. The relationship between the B1 and B2 subunits and the cloned GTH1 and GTH2 cDNA sequences [Rhoads, Zarlengo & Tu (1987) Biochem. Biophys. Res. Commun. 145, 474-481] is discussed.     

The 35- and 36-kDa beta subunits of GTP-binding regulatory proteins are products of separate genes

The wide range of functions attributed to GTP-binding regulatory proteins (G proteins) is reflected in the structural diversity which exists among the alpha, beta, and gamma subunits of G proteins. Recently two cDNA clones encoding beta subunits, beta 1 and beta 2, were isolated from bovine and human cDNA libraries. We report here that the beta 2 gene encodes the 35-kilodalton (kDa) component of the beta 35/beta 36 subunit of G proteins and that the beta 1 gene encodes the 36-kilodalton component. The in vitro translation product of the beta 2 cDNA co-migrates with the 35-kDa beta subunit (beta 35), while the in vitro product of the beta 1 cDNA co-migrates with the 36-kDa beta subunit (beta 36) on denaturing polyacrylamide gels. In addition, antisera generated against synthetic beta 2 peptides bind specifically to the beta 35 component of isolated G proteins and to a 35-kDa protein in myeloid cell membranes. Our results suggest that the two beta subunits could serve distinct functions, as they are derived from separate genes which have been highly conserved in evolution.     

Interaction of the mycotoxin penicillic acid with glutathione and rat liver glutathione S-transferases

The in vitro interaction of the mycotoxin penicillic acid (PA) with rat liver glutathione S-transferase (GST) was studied using reduced glutathione and 1-chloro-2,4-dinitrobenzene as substrates. The inhibition of the GST activity by PA in crude extracts was dose dependent. Each of the different GST isoenzymes was inhibited, albeit at different degrees. Kinetic studies never revealed competitive inhibition kinetics. The conjugation of PA with GSH occurred spontaneously; it was not enzymatically catalyzed by GST, indicating that an epoxide intermediate is not involved in conjugation. The direct binding of PA to GST provides an additional detoxication mechanism.     

Isoelectric focusing of glutathione S-transferases from rat liver and kidney

The glutathione S-transferases that were purified to homogeneity from liver cytosol have overlapping but distinct substrate specificities and different isoelectric points. This report explores the possibility of using preparative electrofocusing to compare the composition of the transferases in liver and kidney cytosol. Hepatic cytosol from adult male Sprague–Dawley rats was resolved by isoelectric focusing on Sephadex columns into five peaks of transferase activity, each with characteristic substrate specificity. The first four peaks of transferase activity (in order of decreasing basicity) are identified as transferases AA, B, A and C respectively, on the basis of substrate specificity, but the fifth peak (pI6.6) does not correspond to a previously described transferase. Isoelectric focusing of renal cytosol resolves only three major peaks of transferase activity, each with narrow substrate specificity. In the kidney, peak 1 (pI9.0) has most of the activity toward 1-chloro-2,4-dinitrobenzene, peak 2 (pI8.5) toward p-nitrobenzyl chloride, and peak 3 (pI7.0) toward trans-4-phenylbut-3-en-2-one. Renal transferase peak 1 (pI9.0) appears to correspond to transferase B on the basis of pI, substrate specificity and antigenicity. Kidney transferase peaks 2 (pI8.5) and 3 (pI7.0) do not correspond to previously described glutathione S-transferases, although kidney transferase peak 3 is similar to the transferase peak 5 from focused hepatic cytosol. Transferases A and C were not found in kidney cytosol, and transferase AA was detected in only one out of six replicates. Thus it is important to recognize the contribution of individual transferases to total transferase activity in that each transferase may be regulated independently.     

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.     

A comparison of the glutathione S-transferases of trout and rat liver.

1. Cytosol from trout liver, gills and intestinal caeca has substantial glutathione S-transferase activity. 2. Gel-exclusion and ion-exchange chromatography suggest that trout liver has several glutathione S-transferases with different molecular weights and ionic charges. 3. A component capable of binding lithocholic acid eluted together with glutathione S-transferase activity. Some of the transferase activity did not elute together with binding activity. 4. The enzymic activity from trout liver was less stable at 37 degrees C than that from rat liver. 5. The glutathione S-transferases of fish liver have a similar specific activity to those of rat liver but different molecular properties.     

Binding of bile acids by glutathione S-transferases from rat liver

Binding of bile acids and their sulfates and glucuronides by purified GSH S-transferases from rat liver was studied by 1-anilino-8-naphthalenesulfonate fluorescence inhibition, flow dialysis, and equilibrium dialysis. In addition, corticosterone and sulfobromophthalein (BSP) binding were studied by equilibrium and flow dialysis. Transferases YaYa and YaYc had comparable affinity for lithocholic (Kd approximately 0.2 microM), glycochenodeoxycholic (Kd approximately to 60 microM), and cholic acid (Kd approximately equal 60 microM), and BSP (Kd approximately 0.09 microM). YaYc had one and YaYa had two high affinity binding sites for these ligands. Transferases containing the Yb subunit had two binding sites for these bile acids, although binding affinity for lithocholic acid (Kd approximately 4 microM) was lower than that of transferases with Ya subunit, and binding affinities for the other bile acids were comparable to the Ya family. Sulfated bile acids were bound with higher affinity and glucuronidated bile acids with lower affinity by YaYa and YaYc than the respective parent bile acids. In the presence of GSH, binding of lithocholate by YaYc was unchanged and binding by YbYb' was inhibited. Conversely, GSH inhibited the binding of cholic acid by YaYc but had less effect on binding by YbYb'. Cholic acid did not inhibit the binding of lithocholic acid by YaYa.     

Differential induction of class alpha glutathione S-transferases in mouse liver by the anticarcinogenic antioxidant butylated hydroxyanisole. Purification and characterization of glutathione S-transferase Ya1Ya1.

A novel cytosolic Alpha class glutathione S-transferase (GST) that is not normally expressed in mouse liver was found to be markedly induced (at least 20-fold) by the anti-carcinogenic compound butylated hydroxyanisole. This enzyme (designated GST Ya1 Ya1) did not bind to either the S-hexylglutathione-Sepharose or the glutathione-Sepharose affinity matrices, and purification was achieved by using bromosulphophthalein-glutathione-Sepharose. The purified isoenzyme, which comprises subunits of Mr 25,600, was characterized, and its catalytic, electrophoretic, immunochemical and structural properties are documented. GST Ya1 Ya1 was shown to be distinct from the Alpha class GST that is expressed in normal mouse liver and is composed of 25,800-Mr subunits; the Alpha class isoenzyme that is constitutively expressed in the liver is now designated GST Ya3 Ya3. Hepatic concentrations of GST Ya3 Ya3 were not significantly affected when mice were treated with butylated hydroxyanisole. Both Pi class GST (subunit Mr 24,800) and Mu class GST (subunit Mr 26,400) from female mouse liver were induced by dietary butylated hydroxyanisole. By contrast, hepatic concentrations of microsomal GST (subunit Mr 17,300) were unaffected.     

Tissue-specific expression of the rat glutathione S-transferases

Tissue-specific patterns of rat glutathione S-transferase expression have been demonstrated by in vitro translation of purified poly(A) RNAs and by protein purification. Poly(A) RNAs from six rat tissues including heart, kidney, liver, lung, spleen, and testis were used to program in vitro translation with the rabbit reticulocyte lysate system and [35S]methionine. The glutathione S-transferase subunits synthesized in vitro were purified from the translation products by affinity chromatography on S-hexylglutathione-linked Sepharose 6B columns. The affinity bound fractions were analyzed by Na dodecyl SO4-polyacrylamide gel electrophoresis and fluorography. A subunit of Mr = 22,000 detected in the in vitro translation products of poly(A) RNAs from heart, kidney, lung, spleen, and testis is missing from the translation products of liver poly(A) RNAs. This Mr = 22,000 subunit is present only in the anionic glutathione S-transferase fraction purified from rat heart, kidney, lung, spleen, and testis. Purified anionic glutathione S-transferase from rat liver does not contain this subunit. The relative specific activities toward a dozen different substrates also demonstrate the nonidentity between liver and kidney anionic glutathione S-transferases. In addition, among the glutathione S-transferase subunits expressed in the liver, some of them could not be detected in the other tissues investigated. Our results indicate that tissue-specific expression of rat glutathione S-transferases may occur pretranslationally.     

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.