The Yc and Ya subunits of rat liver glutathione S-transferases are the products of separate genes

SV40 and adenovirus may act as cocarcinogens by downregulating glutathione S-transferase expression

We have discovered a novel function of the SV40 T antigen and the adenovirus E1A proteins: the ability to downregulate the endogenous expression of an important detoxification enzyme, glutathione S-transferase alpha (GST alpha). GST alpha mRNA is much less abundant in rat and human cells that express SV40 T antigen than in the parental cell lines. This GST alpha downregulation does not require expression of SV40 small t antigen or complex formation between large T antigen and p53, p300, or the pRb family of proteins. As might be predicted, cells that express SV40 T antigen are more sensitive than normal cells to alkylating drugs, which GST alpha is known to detoxify. Finally, GST alpha expression is also downregulated in cells that express the adenovirus E1A proteins. We propose that by downregulating GST alpha expression and inactivating p53 function, SV40 and adenovirus may contribute to the initiation of, or the progression toward, malignancy. Thus, in their quest to establish persistent infections, these viruses may inadvertently make the cellular environment more permissive for tumorigenesis.

Rates of amino acid evolution in the 26- and 28-kDa glutathione S-transferases of Schistosoma

Statistical analysis of glutathione S-transferase (GST) sequences of Schistosoma mansoni, Schistosoma japonicum, and other animals revealed that, in comparison both to the related mammalian alpha GSTs and to Schistosoma 26-kDa GSTs, the 28-kDa GSTs of Schistosoma have evolved unusually rapidly at the amino acid level in the ordinarily conserved N-terminal portion of the molecule. Because this rapid rate of evolution is reflected at the amino acid level and at nonsynonymous nucleotide sites but not at synonymous nucleotide sites, it must be due to a relaxation of functional constraint on the N-terminal region of the Schistosoma 28-kDa GSTs rather than to a high mutation rate. By contrast, the 26-kDa GSTs of Schistosoma not only show a slower rate of amino acid evolution in the N-terminal portion than the 28-kDa GSTs but also have evolved more slowly in the C-terminal portion than have the related mammalian mu GSTs. The two 26-kDa GSTs of S. mansoni show particularly strong amino acid conservation between one another in the N-terminal region and a predominance of conservative amino acid replacements.

Time course of glutathione S-transferase elevation in Walker mammary carcinoma cells following chlorambucil exposure

Resistance of Walker 256 rat mammary carcinoma cells to chlorambucil has been shown to be accompanied by a specific increase in the A2-2 subunit of glutathione S-transferase (GST) (Buller et al., Mol Pharmacol 31: 575-578, 1987). Analysis of the time course of GST activity following chlorambucil exposure revealed a 7.5- and 3-fold elevation on day 7 post-treatment in Walker-sensitive (WS) and Walker-resistant (WR) cells, respectively. Flow activated cell sorting (FACS) analyses using antibodies specific for rat liver cytosolic GST supported these results and demonstrated the heterogeneous response of WS cells to chlorambucil exposure. The range of GST levels in drug-treated cells was very broad as compared to that of untreated cells. Transcripts for each class of GST (alpha, mu and pi) were quantified for days 1-9 post-treatment from densitometric scans of RNA slot blots. Elevations in GST alpha RNA preceded increases in GST activity (day 7) in both WS and WR cells. Because fluctuations in GSTA1-1 transcripts were not observed, it was concluded that the increased expression of the alpha class must be attributed to increases in GSTA2-2 transcripts. Amplification of the GST genes in drug-treated cells was not present. These results support the role of GSTA2-2 in the detoxification of chlorambucil. The time course of the cellular response to chlorambucil suggests that the elevation of GSTA2-2 transcripts following alkylating agent exposure may represent only one component of a series of events which collectively confer protection and lead to the establishment of drug resistance.

Glutathione S-transferases: gene structure and regulation of expression

The current knowledge about the structure of GST genes and the molecular mechanisms involved in regulation of their expression are reviewed. Information derived from the study of rat and mouse GST Alpha-class, Ya genes, and a rat GST Pi-class gene seems to indicate that a single cis-regulatory element, composed of two adjacent AP-1-like binding sites in the 5'-flanking region of these GST genes, is responsible for their basal and xenobiotic-inducible activity. The identification of Fos/Jun (AP-1) complex as the trans-acting factor that binds to this element and mediates the basal and inducible expression of GST genes offers a basis for an understanding of the molecular processes involved in GST regulation. The induction of expression of Fos and Jun transcriptional regulatory proteins by a variety of extracellular stimuli is known to mediate the activation of target genes via the AP-1 binding sites. The modulation of the AP-1 activity may account for the changes induced by growth factors, hormones, chemical carcinogens, transforming oncogenes, and cellular stress-inducing agents in the pattern of GST expression. Recent observations implying reactive oxygen as the transduction signal that mediates activation of c-fos and c-jun genes are presently considered to provide an explanation for the induction of GST gene expression by chemical agents of diverse structure. The possibility that these agents may all induce conditions of oxidative stress by various pathways to activate expression of GST genes that are regulated by the AP-1 complex is discussed.

Coamplification of mu class glutathione S-transferase genes and an adenylate deaminase gene in coformycin-resistant Chinese hamster fibroblasts

In Chinese hamster fibroblasts, we previously detected an expressed gene located near the AMP deaminase gene. This gene was named Y1. Upon selection for resistance to coformycin, an inhibitor of AMP deaminase activity, both genes were amplified in several mutants. We have determined the complete nucleotide sequence of Y1 cDNA and identified the Y1 gene as a mu class glutathione S-transferase gene by comparison with sequences present in a data bank. Accordingly, Y1-amplified mutants express an increased glutathione S-transferase activity toward 1-chloro-2,4-dinitrobenzene; this activity, as well as the abundance of the corresponding RNA, appears, however, to reach a limit despite further increase in the Y1 gene copy number during successive amplification steps. Southern blot experiments showed that Y1 belongs to a multigene family, all or part of which has been amplified in mutant lines. These data provide a method to amplify and to overexpress the mu class of the glutathione S-transferase gene family on the basis of its linkage with the AMP deaminase gene.

Identification of rat liver glutathione S-transferase Yb subunits by partial N-terminal sequencing after electroblotting of proteins onto a polyvinylidene difluoride membrane from an analytical isoelectric focusing gel

Rat liver glutathione S-transferases were partially purified using S-hexyl glutathione affinity chromatography, followed by native isoelectric focusing employing a pH 7-11 or pH 3-10 gradient. Proteins were excised and eluted from the gel for determination of subunit composition using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In separate experiments, isoelectric focusing gels were equilibrated with a sodium dodecyl sulfate-containing buffer at high pH, and proteins on the gel were electroblotted onto a polyvinylidene difluoride membrane, utilizing graphite plates as electrodes. The membrane-bound proteins were visualized by Coomassie Brilliant Blue staining. The protein bands were then excised from the membrane and inserted into a gas phase sequenator for direct sequencing. N-Terminal sequences thus determined were compared with published cDNA sequences. The isoelectric points (pIs) and positions on the isoelectric focusing gel of Yb1Yb1, Yb1Yb2 and Yb2Yb2 subunits were determined. We have also located on the pH 3-10 focusing gel an N-terminal blocked glutathione S-transferase which has a molecular weight similar to Yb subunits.

Molecular cloning and tissue distribution of a 26-kilodalton Schistosoma mansoni glutathione S-transferase

A Schistosoma mansoni cDNA library was constructed from the mRNA of adult worms in the expression vector lambda gt11 and screened with a rabbit antiserum raised against the 26-kDa S. mansoni glutathione S-transferase isoforms (Sm GST 26). Two clones were selected and the nucleotide sequences deduced. The predicted amino acid sequence, specified by these cDNAs, shows strong homology with a Schistosoma japonicum 26 kDa glutathione S-transferase and a lower level of homology with mammalian glutathione S-transferase class mu isoenzymes (EC 2.5.1.18). No significant homology score was found with a 28-kDa S. mansoni glutathione S-transferase (Sm GST 28). A study of the tissue distribution of the cloned Sm GST 26 by immunoelectron microscopy shows similarities to Sm GST 28 in that they are present in the tegument and in subtegumentary parenchymal cells. However, a major difference exists in the protonephridial region in which Sm GST 26 is present in the cytoplasmic digitations localized in the apical chamber delineated by the flame cell body, suggesting that Sm GST 26 may be actively excreted by adult worms.

Characterization of a variant rat glutathione S-transferase by cDNA expression in Escherichia coli

We have isolated a glutathione S-transferase Yb1 subunit cDNA from a lambda gt11 cDNA collection constructed from rat testis poly(A) RNA enriched for glutathione S-transferase mRNA activities. This Yb1 cDNA, designated pGTR201, is identical to our liver Yb1 cDNA clone pGTR200 except for a shorter 5'-untranslated sequence. Active glutathione S-transferase is expressed from this Yb1 cDNA driven by the tac promoter on the plasmid construct pGTR201-KK. The expressed glutathione S-transferase protein begins with the third codon (Met) of the cDNA, and is missing the N-terminal proline of rat liver glutathione S-transferase 3-3. Therefore, our Escherichia coli expressed glutathione S-transferase protein represents a variant form of glutathione S-transferase 3-3 (Yb1Yb1), designated GST 3-3(-1). The expressed Yb1 subunits are assembled into a dimer as purified from sonicated E. coli crude extracts. In the absence of dithiothreitol three active isomers can be resolved by ion-exchange chromatography. The pure protein has an extinction coefficient of 9.21 x 10(4) M-1 cm-1 at 280 nm or E0.1% 280 = 1.78 and a pI at 8.65. It has a substrate specificity pattern similar to that of the authentic glutathione S-transferase 3-3. The GST 3-3(-1) has a KM of 202 microM for reduced GSH and of 36 microM for 1-chloro-2,4-dinitrobenzene. The turnover number for this conjugation reaction is 57 s-1. Results of kinetic studies of this reaction with GST 3-3(-1) are consistent with a sequential substrate binding mechanism. We conclude that the first amino acid proline of glutathione S-transferase 3-3 is not essential for enzyme activities.

The glutathione S-transferases: an update

Over the last 15 years, we have passed through an initial period in which multiple forms of GST in various organs and different species were identified and characterized. The focus of current research is to define the role of the numerous isozymes in cell function, to ascertain the relationship between structure and function of different isozymes and to determine how the expression of GST is regulated in different tissues. During these studies, it is expected that new roles for the GST will be proposed, and this family of multifunctional proteins will continue to hold the interest of numerous investigators for many years.

Biochemical and immunological demonstration of prostaglandin D2, E2, and F2 alpha formation from prostaglandin H2 by various rat glutathione S-transferase isozymes

Glutathione S-transferase isozymes purified from normal rat liver (1-1, 1-2, 2-2, 3-3, 3-4, and 4-4), liver with hyperplastic nodules (7-7), brain (Yn1Yn1), and testis (Yn1Yn2) all had prostaglandin H2-converting activity. The prostaglandin H2 E-isomerase activity was high in 1-1 (1400 nmol/min/mg protein), 1-2 (1170), and 2-2 (420), moderate in 3-3, 3-4, 4-4, Yn1Yn1, and Yn1Yn2 (52-100), and weak but significant in 7-7 (33). The prostaglandin H2 D-isomerase activity was relatively high in 1-1 (170) and 1-2 (200), moderate in 2-2 (60) and Yn1Yn2 (43), and weak but marked in 3-3 (16), 4-4 (16), and 7-7 (14). The prostaglandin H2 F-reductase activity was remarkable in 1-1 (1250), 1-2 (920), and 2-2 (390), and weakly detected in 3-3 (24), 4-4 (28), and 7-7 (14). Glutathione was absolutely required for these prostaglandin H2-converting reactions, and its stoichiometric consumption was associated with F-reductase activity but not E- and D-isomerase activities. The Km values for glutathione and prostaglandin H2 were about 200 and 10-40 microM, respectively. By immunoabsorption analyses with various antibodies specific for each isozyme, we examined its contribution to the formation of prostaglandins D2, E2, and F2 alpha from prostaglandin H2 in 100,000g supernatants of rat liver, kidney, and testis. In the liver, about 90% of the F-reductase activity (9.8 nmol/min/mg protein) was shown to be catalyzed by the 1-2 group of isozymes. The E-isomerase activity (16.5) was catalyzed about 60 and 40% by the 1-2 and 3-4 groups, respectively; and the D-isomerase activity (3.7) was catalyzed by the 1-2 group (50%) and the 3-4 group and Yn1Yn2 (15-25%). In the kidney, the E-isomerase activity (9.4) was catalyzed by 1-1, 1-2 (40%), 2-2, 3-4 group, and 7-7 (10-20%). The F-reductase activity (3.3) was mostly catalyzed by the 1-2 group (75%). In the testis, the E-isomerase activity (3.9) was catalyzed by the 1-2 group (20-30%), the 3-4 group, and Yn1Yn2 (30-60%).

A survey on cytosolic non-enzymic proteins involved in the metabolism of lipophilic compounds: from organic anion binders to new protein families

This review deals with recent advances in the research of cytosolic non-enzymic proteins involved in the metabolism of lipophilic compounds. Emphasis is given to the important contribution of structural data in the understanding of the functional properties of these proteins and in the emergence of new protein families. The possibility that many of the 'cytosolic' proteins might be structure-bound and structure-forming in the living cell is discussed, with references to so far available structural data and to recent investigations on the architecture and biochemical composition of the cytoplasm. The aim of this review is to present in a condensed form (227 references) the evolution in the study of cytosolic proteins binding and transferring lipophilic compounds and to enable interested investigators to become aware of current concepts and perspectives in this active and steadily growing area of research.

Crystallization and a preliminary X-ray diffraction study of isozyme 3-3 of glutathione S-transferase from rat liver

Crystals of the homodimeric isozyme 3-3 of glutathione S-transferase from rat liver have been obtained with the hanging drop method of vapor diffusion from ammonium sulfate solutions. The successful crystallization of the enzyme required the presence of both the enzyme inhibitor (9R, 10R)-9, 10-dihydro-9-(S-glutathionyl)-10-hydroxyphenanthrene and the detergent beta-octylglucopyranoside. The crystals belong to the monoclinic space group C2, with cell dimensions of a = 88.24(8) A, b = 69.44(4) A, c = 81.28(5) A, beta = 106.01(6) degrees, and contain four dimeric enzyme molecules per unit cell. The crystals diffract to at least 2.2 A and are suitable for X-ray crystallographic structure determination at high resolution.

Mouse glutathione S-transferase Ya subunit: gene structure and sequence

A mouse glutathione S-transferase gene encoding the Ya subunit was isolated and sequenced. The gene spans about 11 kb, contains seven exons, and encodes an mRNA of 841 nucleotides. Promoter elements, TATA and CAAT box sequences, were located 32 and 70 nucleotides upstream from the initiation of transcription site. The mRNA coding sequences of the mouse gene were highly homologous to a rat liver Ya mRNA species detected by cDNA cloning. The mouse Ya gene produces a 223-amino-acid polypeptide that differs from the 222-amino-acid rat Ya by 10 amino acid substitutions and a carboxyl terminus Phe-Lys-Ile-Gln instead of Phe-Lys-Phe. A genomic clone containing the last three exons of the rat Ya gene was also isolated, sequenced, and compared with the mouse Ya gene. An extensive sequence conservation (70-80%) in the 50 to 200 bases of introns at the exon-intron junctions as well as in the region beyond the cleavage-polyadenylation site of pre-mRNA was observed.

Synthesis of subunits of ligandin by isolated hepatocytes

The pulse-chase technique was employed to determine the synthesis of the subunits of ligandin (glutathione S-transferase 1-2) by isolated hepatocytes. Ligandin comprised 2.5-3% of the total proteins synthesized. A slightly higher incorporation of [35S]methionine into the 22 k than the 25 k subunit was observed. However, the ratio of [35S]methionine incorporation into the subunits remained constant throughout the chase period, suggesting that, in spite of the considerable sequence homology, the conversion of 25 k to 22 k subunit does not occur in vivo.

Sequence analysis and regulation of rat liver glutathione S-transferase mRNAs

We have utilized polysomal immunoadsorption techniques to purify the rat liver glutathione S-transferase mRNAs. Using the purified mRNAs as template, cDNA clones complementary to the Ya, Yb1, and Yc mRNAs have been constructed. The cDNA clones have been utilized in RNA blot hybridization and nuclear run-off assays to demonstrate that the Ya and Yb mRNAs are elevated 8 and 5-fold, respectively by phenobarbital; whereas the Yc mRNA is elevated only 2.0-fold. The elevation in glutathione S-transferase mRNAs is due in part to transcriptional activation of the corresponding genes. Nucleotide sequence analysis of the three glutathione S-transferase clones suggest that the Ya and Yc genes represent one rat liver glutathione S-transferase gene family whereas the Yb genes represent a second distinct glutathione S-transferase gene family. The construction of these cDNA clones will allow identification and characterization of the glutathione S-transferase structural genes as well as aid in the identification of regulatory elements that are responsible for transcriptional activation of the genes by xenobiotics.

Isolation of a human liver ligandin cDNA clone and demonstration of sequence homology at ligandin loci in rats and humans

Using a monospecific antibody to the major cytosolic glutathione-S-transferase of human liver, we have isolated a cDNA clone from a human liver cDNA expression vector library in lambda gt11. The clone cross-hybridizes with a rat liver ligandin (glutathione-S-transferase 1-2) cDNA probe. The clone has an insert of 1.25 kb, a size sufficient to code for the 23 kilodalton subunit of human GST. Digestion of the insert with Hinf I produced three fragments (0.8 kb, 0.4 kb and 0.1 kb). A similar pattern of multiple bands was observed when rat liver GST1-2 cDNA probe was used for Southern blot analysis of Pst digests of rat and human genomic DNAs. These data suggest that these two functionally similar proteins exhibit sequence homology between their respective cDNAs and at ligandin loci, in spite of the lack of immuno-crossreactivity between them.

Enzyme-catalyzed detoxication reactions: mechanisms and stereochemistry

Enzyme catalyzed detoxication reactions are one of the primary defenses organisms have against chemical insult. This article reviews current chemical approaches to understanding the cooperative role of enzymes in the metabolism of foreign compounds. Emphasis is placed on chemical and stereochemical studies which help elucidate the mechanism of action and active-site topologies of the detoxication enzymes. The stereoselectivity of the cytochromes P-450 and flavin containing monooxygenases as well as the role of hemoglobin and lipid peroxidation in the primary metabolism of xenobiotics is discussed. Current knowledge of the mechanism and stereoselectivity of epoxide hydrolase is also presented. Three enzymes involved in secondary metabolism of xenobiotics, UDP-glucuronosyltransferase, sulfotransferase and glutathione S-transferase are discussed with particular emphasis on active site topology and cooperative participation with the enzymes of primary metabolism.

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.

Differential regulation of hepatic glutathione transferase and glutathione peroxidase activities in the rat

The effects of the xenobiotics, i.e. butylated hydroxytoluene, beta-naphthoflavone, isosafrole, pregnenolone-16 alpha-carbonitrile, trans-stilbene oxide, 3-methylcholanthrene, phenobarbital, 3,3',4,4'-tetrachlorobiphenyl, 2,2',4,4',5,5'-hexachlorobiphenyl, on rat liver cytosolic glutathione transferase and glutathione peroxidase activities have been investigated. Although the glutathione transferase isozymes (measured by the specific substrates ethacrynic acid and delta 5-androstene-3,17-dione) which have been shown to possess peroxidase activity were significantly increased, little or no increase in peroxidase activity (toward cumene hydroperoxide, tert-butyl hydroperoxide or hydrogen peroxide) was observed. Likewise during a 16-day time course following the administration of Aroclor 1254 or fireMaster BP-6 (each 500 mg/kg, i.p.), potent induction of glutathione transferase activities was seen without any significant increases in peroxidase activities. In fact during the second week of the time course, there were significant decreases in selenium-dependent glutathione peroxidase activity (toward hydrogen peroxide). The inverse regulation of these activities, i.e. the depression of selenium-dependent glutathione peroxidase activity following sustained induction of glutathione transferases, may have direct implications for the toxicity of the polyhalogenated aromatic hydrocarbons.

Transcriptional regulation of rat liver glutathione S-transferase genes by phenobarbital and 3-methylcholanthrene

The relative rates of transcription of the rat liver glutathione S-transferase Ya-Yc and Yb genes were determined in purified liver nuclei isolated at different times after phenobarbital or 3-methylcholanthrene administration. The transcriptional rates of the Ya-Yc and Yb genes were elevated approximately fivefold 8 and 6 h, respectively, after phenobarbital administration. In contrast, the transcriptional rates of the Ya-Yc genes were elevated approximately eightfold at 16 h after 3-methylcholanthrene administration, whereas the transcriptional rates of the Yb genes were elevated approximately fivefold at 6 h after the administration of this xenobiotic. The elevation in transcriptional activity of the glutathione S-transferase genes is sufficient to account for the increase in glutathione S-transferase mRNA levels determined previously by RNA blot hybridization [C. B. Pickett, C. A. Telakowski-Hopkins, G. J-F. Ding, L. Argenbright, and A. Y. H. Lu (1984) J. Biol. Chem. 259, 5182-5188]. Therefore, it appears that phenobarbital and 3-methylcholanthrene elevate the level of the rat liver glutathione S-transferases primarily by augmenting the transcriptional rates of their respective genes.