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.     

Nucleotide sequence of the yeast glutathione S-transferase cDNA

The nucleotide sequence (658 bp) of the cDNA coding for glutathione S-transferase Y-2 of yeast Issatchenkia orientalis was obtained. The cDNA clone contains an open reading frame of 570 nucleotides encoding a polypeptide comprising 190 amino acids with a molecular weight of 21,520. The primary amino acid sequence of the enzyme exhibits only 25.0% and 21.1% identity with 177 and 151 amino acid residues of maize glutathione S-transferase I and rat glutathione S-transferase Yb2, respectively.     

Gene expression of rat glutathione S-transferases. Evidence for gene conversion in the evolution of the Yb multigene family

We have characterized a cDNA with complete coding sequence for the rat liver glutathione S-transferase subunit 4 (Yb2) isolated from a constructed lambda gt10 cDNA library. Functional expression of the cDNA sequence has resulted in the purification to homogeneity of an enzymatically active anionic glutathione S-transferase. In addition to three previously described Yb-type subunits (Yb1, Yb2, Yb3), we now report characterization of a fourth Yb subunit sequence in the form of a genomic DNA clone lambda GTR15-2. The Yb4 gene has no apparent defect, and the deduced Yb4 polypeptide sequence differs from the other three Ybs by 40 to 53 amino acids. The Yb4 gene organization is similar to that of the Yb2 gene in having a minimum of eight exons. Three out of the seven introns between the two genes are conserved to the extent of more than 88% nucleotide identity. We propose that gene conversion may have played a role in the evolution of these Yb 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.     

Identification of glutathione S-transferase Yb1 mRNA as the androgen-repressed mRNA by cDNA cloning and sequence analysis

Androgens, while stimulating the growth of the rat ventral prostate, can also repress the levels of a limited number of mRNAs. The cDNA for one of the androgen-repressed mRNAs has been identified by nucleotide sequence analysis as coding for the glutathione S-transferase Yb1 subunit. The prostate cDNA is 1071 nucleotides long, and only 2 or 4 bases of this sequence do not match the two published sequences of the cDNA for the Yb1 subunit of rat liver glutathione S-transferase. The amino acids in the protein encoded by the prostate cDNA matched completely with that for one of the liver cDNAs and differ with the other cDNA only in two of 218 amino acids. The identification of the androgen-repressed mRNA as a glutathione S-transferase subunit may indicate that some of the cellular actions of the enzyme may be important in the control of androgen-dependent growth of the prostate. Since Yb forms of the transferases have been colocalized with uridylic acid-rich small nuclear RNAs at interchromatinic regions of the cell nucleus, autoregulation of prostate growth by androgens may be carried out through the modulation of RNA production or processing in this target organ.     

The human liver glutathione S-transferase gene superfamily: expression and chromosome mapping of an Hb subunit cDNA.

We have isolated from a lambda gt10 cDNA library a clone lambda GTH4 which encodes a human liver glutathione S-transferase Hb subunit, designated as subunit 4. Expression of this cDNA in E. coli and subsequent purification and immunoblotting analysis provided a definitive assignment of a structure and function relationship. RNA blot hybridization with human liver poly(A) RNA revealed a single band of approximately 1200 nucleotides, comparable in size to the rat brain Yb3 mRNA. Divergence analysis of amino acid replacement sites in subunit 4 relative to the four rat Yb subunits revealed that it is most closely related to the brain-specific Yb3 subunit. This conclusion is further substantiated by the nucleotide sequence homology between lambda GTH4 and the Yb3 cDNA in their 3' untranslated region. In situ chromosome mapping has located this glutathione S-transferase gene in the region of p31 on chromosome 1. Results from many laboratories, including ours, indicate that the human glutathione S-transferases are encoded by a gene superfamily which is located on at least two different chromosomes.     

Expression of an enzymatically active Yb3 glutathione S-transferase in Escherichia coli and identification of its natural form in rat brain

Glutathione S-transferases containing Yb3 subunits are relatively uncommon forms that are expressed in a tissue-specific manner and have not been identified unequivocally or characterized. A cDNA clone containing the entire coding sequence of Yb3 glutathione S-transferase mRNA was incorporated into a pIN-III expression vector used to transform Escherichia coli. A fusion Yb3-protein containing 14 additional amino acid residues at its N terminus was purified to homogeneity. Recombinant Yb3 was enzymatically active with both 1-chloro-2,4-dinitrobenzene and 1,2-dichloro-4-nitrobenzene as substrates but lacked glutathione peroxidase activity. Substrate specificity patterns of recombinant Yb3 were more limited than those of glutathione S-transferase isoenzymes containing Yb1- or Yb2-type subunits. Peptides corresponding to unique amino acid sequences of Yb3 as well as a peptide from a region of homology with Yb1 and Yb2 subunits were synthesized. These synthetic peptides were used to raise antibodies specific to Yb3 and others that cross-reacted with all Yb forms. Immunoblotting was utilized to identify the natural counterpart of recombinant Yb3 among rat glutathione transferases. Brain and testis glutathione S-transferases were rich in Yb3 subunits, but very little was found in liver or kidney. Physical properties, substrate specificities, and binding patterns of the recombinant protein paralleled properties of the natural isoenzyme isolated from brain.     

Selective induction of glutathione S-transferase D in rat testis by phenobarbital

Testis cytosol is shown to contain the Yb2Yb2 -homodimer glutathione S-transferase D in addition to the previously described glutathione S-transferases A ( Yb1Yb1 ) and C ( Yb1Yb2 ). Treatment of rats with phenobarbital induces the level of glutathione S-transferase D in testis with no increase in the activities of glutathione S-transferases A and C. This result indicates a specific induction of the Yb2 subunit in testis, in contrast with the situation in rat liver, where phenobarbital specifically induces the Yb1 subunit.     

Identification of heterogeneous and microheterogeneous subunits of glutathione S-transferase in rat liver cytosol

Subunits of multiple molecular forms of dimeric glutathione S-transferase in rat liver cytosol were analyzed by two-dimensional gel electrophoresis (isoelectric focusing/sodium dodecyl sulfate-electrophoresis) followed by staining with Coomassie blue dye. The five subunits, Ya, Yb, Yb', Yc, and Yp (Mr's 26,500, 27,500, 27,500, 28,500, and 26,000, respectively) of seven molecular forms, A2, AC, C2, B2, BL, L2, and GST-P, were identified by comparison of molecular weights and pI values with those of purified molecular forms and by immunoadsorption of the molecular forms in the cytosol as well as those synthesized in vitro using antibodies against the seven forms. Yp is the subunit of placental glutathione S-transferase, GST-P (YpYp), which is markedly increased in carcinogen-treated rat livers [A. Kitahara et al. (1984) Cancer Res. 44, 2698-2703; K. Satoh et al. (1985) Proc. Natl. Acad. Sci. USA 82, 3964-3968]. Microheterogeneity was detectable within Yb, Yb', and Yp subunits, the different forms, termed Yb1, Yb2, Yb'1, Yb'2, and Yp1, Yp2, being similar in size but differing by approx. 0.3 pI unit within each subunit. These microheterogeneous forms were also detectable in the polypeptides translated in vitro in a rabbit reticulocyte lysate translation system from liver poly(A)-containing RNAs, suggesting that they are translatable from distinct mRNAs.     

The identification of a glutathione S-transferase isozyme in fetal rat livers which is absent from adult livers

The subunit composition of adult and fetal rat liver glutathione S-transferase was investigated by affinity chromatography followed by polyacrylamide gel electrophoresis in sodium dodecylsulphate. Adult livers contained four major GSH S-T subunits. A previously unidentified subunit was detected in fetal livers. This subunit(s), which differed from that found in rat placenta, had a molecular weight of about 25,500 daltons, gave two bands of pI 8.0 and 8.5 on isoelectric focussing, and reacted on "Western blots" with antibodies raised against the major GSH S-T subunits of adult liver. Densitometric measurements suggest that the newly detected transferase subunit accounted for as much as 26% of GSH S-T in fetal livers.     

Nucleotide sequence of a class mu glutathione S-transferase from chicken liver

A clone coding for glutathione S-transferase (GST) CL2 was isolated from a chicken liver cDNA library. This clone (819 bp) encodes a polypeptide comprising 219 amino acids with a molecular weight of 25,717, excluding the initiator methionine. The primary amino acid sequence of the enzyme has 47% identical sequence with other class mu GSTs.     

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.     

The requirement for glutathione S-transferase in the conjugation of activated aflatoxin B1 during aflatoxin hepatocarcinogenesis in the rat

The formation of an aflatoxin B1-reduced glutathione (AFB1-GSH) conjugate in in vitro systems has been examined. AFB1 was activated by a chicken liver microsomal system and factors affecting the subsequent conversion to the AFB1-dihydrodiol or conjugation with GSH were investigated by HPLC. A requirement for glutathione S-transferase in the formation of the AFB1-GSH conjugate was observed. Studies using CM-cellulose columns showed the fractions containing glutathione S-transferase B activity were the most effective in catalysing the formation of the AFB1-GSH conjugate. The possibility of changes in the level of AFB1-GSH conjugate production in the liver during carcinogenesis by AFB1 has been examined. It has been found, using freshly isolated rat hepatocytes, that low level feeding with AFB1 in vivo increases the production of the conjugate in vitro. Further increases in the production of the conjugate by hepatocytes in vitro, accompanying increases in the preneoplastic lesions, are achieved by partially hepatectomising the AFB1-fed animals. Partial hepatectomy of control-fed animals yielded no similar changes. The AFB1/partial hepatectomy treatment resulted in increased levels of all the glutathione S-transferase activities fractionated on CM-cellulose. Macromolecular binding of AFB1 and/or of its metabolites was detected in the fractions containing glutathione S-transferase activity, but there was no evidence for a greater binding in the glutathione S-transferase B/ligandin containing fractions. Furthermore fractionation on Sephadex G-75 indicated a predominance of binding of AFB1 to proteins of a higher molecular weight than the glutathione S-transferases, although some binding in the molecular weight range of the latter was observed.     

Glutathione S-transferase from beef heart: structural and kinetic properties

A simple and rapid method for the purification of glutathione S-transferase is described. The physical and kinetic properties of purified enzyme are reported. The protein is constituted of two identical subunits with a total molecular weight of 46,000 daltons. The isoelectric focusing of crude cytosol or purified preparation gives a single peak of activity with a pI of 7.1. The kinetic analysis shows a relatively strict substrate specificity. Only 1-chloro-2,4-dinitrobenzene is conjugated to reduced glutathione at an appreciable rate. The peroxidase activity of the enzyme with respect to cumene hydroperoxide as substrate is negligible. Hemin and bilirubin are competitive inhibitors of catalytic activity.     

Molecular cloning, sequencing, and expression of human myocardial fatty acid ethyl ester synthase-III cDNA

Fatty acid ethyl ester synthase-III (FAEES-III), previously purified to homogeneity from human heart, metabolizes ethanol nonoxidatively. Using a derived partial amino acid sequence and corresponding oligonucleotide probes, the cDNA for this enzyme has been cloned from a human heart lambda gtll library. Of the five positive clones obtained, one contained a complete coding region (630 base pairs) and the entire 3'-noncoding region (41 base pairs). From this nucleotide sequence the complete 210 amino acid sequence of FAEES-III (Mr 23,307) is reported. Comparison of its amino acid sequence with that of glutathione S-transferase pi-1 suggests that they belong to the same gene family since they differ in only six nucleotides and four amino acids. The sequence of FAEES-III was also compared with those of placental glutathione S-transferase and the basic glutathione S-transferase. FAEES-III was 84% homologous with placental glutathione S-transferase but only less than 10% homologous with the basic glutathione S-transferase. Northern blots demonstrate expression of FAEES-III mRNA in normal human liver, placenta, and heart. In all cases, the mRNA for the enzyme is 0.7 kilobase in size. MCF-7 cells transfected with FAEES-III cDNA have a 14-fold increase in synthase activity and a 12-fold increase in glutathione S-transferase (GST) activity compared with control cells. MCF-7 cells transfected with GST pi-1 cDNA have a 13-fold increase in GST activity compared with control cells but no increase in synthase activity. When the supernatant of COS-7 cells transfected with FAEES-III cDNA were immunoblotted with rabbit FAEES-III antibody, a band at 24 kilodaltons was demonstrated. Thus, we have obtained the first cDNA and amino acid sequence for a human FAEES-III which also has significant GST activity, and we have identified 4 residues potentially responsible for conferring ethanol recognition to GSTs.     

Isolation and characterization of a DNA sequence complementary to rat liver glutathione S-transferase B mRNA

Total rat liver poly(A+)-RNA has been isolated from phenobarbital-treated rats and fractionated on sucrose gradients to enrich for glutathione S-transferase B mRNA. Poly(A+)-RNA fractions were assayed for glutathione S-transferase B mRNA activity by in vitro translation and those fractions enriched in glutathione S-transferase B mRNA were used as a template for cDNA synthesis. The cDNA was cloned into the PstI site of pBR322 by G-C tailing. Bacterial clones harboring inserts complementary to glutathione S-transferase mRNA were identified by colony hybridization using a [32P]cDNA probe reverse transcribed from poly(A+)-RNA enriched significantly in glutathione S-transferase B mRNA and by hybrid-select translation. Two recombinant clones, pGTB6 and pGTB15 hybrid-selected the mRNAs specific for the Ya and Yc subunits, indicating these two mRNAs share significant sequence homology. Radiolabeled pGTB6 was utilized in RNA gel-blot experiments to determine that the size of glutathione S-transferase B mRNA is 980 nucleotides and the degree of induction of the mRNA in response to 3-methylcholanthrene administration is threefold.     

Purification and cloning of a Delta class glutathione S-transferase displaying high peroxidase activity isolated from the German cockroach Blattella germanica

A highly active glutathione S-transferase was purified from adult German cockroaches, Blattella germanica. The purified enzyme appeared as a single band of 24 kDa by SDS/PAGE, and had a different electrophoretic mobility than, a previously identified Sigma class glutathione S-transferase (Bla g 5). Kinetic study of 1-chloro-2,4-dinitrobenzene conjugation revealed a high catalytic rate but common substrate-binding and cosubstrate-binding affinities, with V(max), k(cat), K(m) for 1-chloro-2,4-dinitrobenzene and K(m) for glutathione estimated to be 664 micromol x mg(-1) x min(-1), 545 s(-1), 0.33 mm and 0.76 mm, respectively. Interestingly, this enzyme possessed the highest activity for cumene hydroperoxide among insect glutathione S-transferases reported to date. Along with the ability to metabolize 1,1,1-trichloro-2,2-bis(p-chlorophenyl)ethane and 4-hydroxynonenal, this glutathione S-transferase may play a role in defense against insecticides as well as oxidative stress. On the basis of the amino acid sequences obtained from Edman degradation and MS analyses, a 987-nucleotide cDNA clone encoding a glutathione S-transferase (BggstD1) was isolated. The longest ORF encoded a 24 614 Da protein consisting of 216 amino acid residues. The sequence had close similarities ( approximately 45-60%) to that of Delta class glutathione S-transferases, but had only 14% identity to Bla g 5. The putative amino acid sequence contained matching peptide fragments of the purified glutathione S-transferase. ELISA showed that BgGSTD1 bound to serum IgE obtained from patients with cockroach allergy, indicating that the protein may be a cockroach allergen.     

Glutathione peroxidase activities from rat liver

There are two enzymes in rat liver with glutathione peroxidase activity when cumene hydroperoxide is used as substrate. One is the selenium-requiring glutathione peroxidase (glutathione:hydrogen-peroxide oxidoreductase, EC 1.11.1.9) and the other appears to be independent of dietary selenium. Activities of the two enzymes vary greatly among tissues and among animals. The molecular weight of the enzyme with selenium-independent glutathione peroxidase activity was estimated by gel filtration to be 35 000, and the subunit molecular weight was estimated by dodecyl sulfate-polyacrylamide gel electrophoresis to be 17 000. Double reciprocal plots of enzyme activity as a function of substrate concentration produced intersecting lines which are suggestive of a sequential reaction mechanism. The Km for glutathione was 0.20 mM and the Km for cumene hydroperoxide was 0.57 mM. The enzyme was inhibited by N-ethylmaleimide, but not by iodoacetic acid. Inhibition by cyanide was competitive with respect to glutathione and the Ki for cyanide was 0.95 mM. This selenium-independent glutathione peroxidase also catalyzes the conjugation of glutathione to 1-chloro-2,4-dinitrobenzene. Along with other similarities to glutathione S-transferase, this suggests that the selenium-independent glutathione peroxidase and glutathione S-transferase activities in rat liver are of the same enzyme.