Two distinct forms of glutathione transferase from human foetal liver. Purification and comparison with isoenzymes isolated from adult liver and placenta.

Isoelectric focusing of a cytosol fraction from human foetal liver revealed the existence of an acidic and a basic isoenzyme of GSH transferase. The acidic and basic forms of GSH transferase were purified in good yield by use of ion-exchange chromatography on DEAE-cellulose followed by affinity chromatography on S-hexyl-GSH coupled to epoxy-activated Sepharose 6B. The content of the acidic and the basic isoenzymes of GSH transferase together was calculated to constitute 1-2% of the soluble proteins in the hepatic cytoplasm. Physical, catalytic and immunological analyses of the acidic and the basic isoenzymes from foetal liver demonstrated unambiguously that the two forms are different structures with distinct properties. On the other hand, the results show clearly extensive similarities between the foetal acidic transferase and transferase pi from human placenta as well as between the foetal basic form and the basic isoenzymes isolated from adult liver. An exception is that both foetal enzymes seem to be considerably more efficient in catalysing the conjugation of GSH with styrene 7,8-epoxide than the corresponding adult forms of GSH transferase.     

Purification and characterization of a labile rat glutathione transferase of the Mu class.

A labile GSH transferase homodimer termed 11-11 was purified from rat testis by GSH-agarose affinity chromatography followed by anion-exchange f.p.l.c. The enzyme is unstable in the absence of thiol(s) and has relatively low affinity for both 1-chloro-2,4-dinitrobenzene (Km 4.4 mM) and GSH (Km(app.) 4.4mM). Its mobility on SDS/polyacrylamide-gel electrophoresis is slightly less than that of subunits 3 and 4 and its pI is 5.2. Subunit 11 has a blocked N-terminal amino acid residue, but after CNBr cleavage fragments accounting for 113 amino acid residues were sequenced and showed 65% homology with corresponding sequences in subunit 4, indicating that it is a member of the Mu family. GSH transferase 11 is a major isoenzyme in testis, epididymis, prostate and brain and present at lower concentrations in other tissues.     

Mouse hepatic glutathione transferase isoenzymes and their differential induction by anticarcinogens. Specificities of butylated hydroxyanisole and bisethylxanthogen as inducers of glutathione transferases in male and female CD-1 mice.

GSH transferase isoenzymes of class Mu (two forms), class Pi (one form) and class Alpha (two forms) were purified from liver cytosols of female CD-1 mice pretreated with an anticarcinogenic inducer, 2(3)-t-butyl-4-hydroxyanisole. GSH transferases GT-8.7, GT-8.8a and GT-8.8b, GT-9.0, GT-9.3, GT-10.3 and GT-10.6 contained a minimum of six types of subunits distinguishable by structural, catalytic and immunological characteristics. H.p.l.c. analysis of the subunit compositions of affinity-purified GSH transferases from liver cytosols of induced and non-induced male and female CD-1 mice showed that two anticarcinogenic compounds, 2(3)-t-butyl-4-hydroxyanisole and bisethylxanthogen, differed markedly in their specificities as inducers of GSH transferase.     

Differential tissue expression of the glutathione transferase multigene family.

The content of GSH transferase mRNAs in poly(A)-containing RNA isolated from eight rat tissues was examined by immunoprecipitation of cell-free translation products and by Northern blotting. Considerable tissue-specific distribution and heterogeneity of immunoprecipitable GSH transferase subunits 1 and 2 synthesized in vitro was observed. These results were confirmed by Northern blotting using a 32P-labelled subunit 1 cDNA probe. The same probe, used in a Southern blot analysis of genomic DNA, provided confirmation that GSH transferase subunits 1 and 2 comprise a multigenic family in the rat. The results show that the selection of cDNA clones coding for chosen subunits can be made easier by making use of qualitative and quantitative tissue differences in GSH transferase mRNAs.     

The glutathione transferase activity and tissue distribution of a cloned Mr28K protective antigen of Schistosoma mansoni.

A protective Mr28K antigen of Schistosoma mansoni, expressed from its cDNA, has been purified in a single step and shown to possess glutathione (GSH) transferase activity as predicted from sequence homologies with two mammalian GSH transferase multigene families. It is notable for its high 1-chloro-2,4-dinitrobenzene GSH transferase and linoleic acid hydroperoxide GSH peroxidase activities. The major GSH transferase of S. mansoni has been purified and its subunit is identical to this Mr28K antigen by criteria of Mr, immunochemistry, substrate specificity and peptide sequence analysis. In the parasite, the antigen is present in the tegument, protonephridial cells and subtegumental parenchymal cells. No significant immunological cross-reactivity between the S.mansoni and mammalian (human and rat) GSH transferases was observed.     

Glutathione transferases: a possible role in the detoxication and repair of DNA and lipid hydroperoxides

Two types of GSH peroxidase occur in the cell both of which detoxify fatty acid hydroperoxides, thymine hydroperoxide and DNA hydroperoxides. One is a Se-dependent enzyme which also detoxifies H2O2. The other contains members of the GSH transferase supergene family. These non-selenium dependent GSH peroxidases do not detoxify H2O2 and have substrate specificities varying markedly with the isoenzyme. Of particular interest is GSH transferase 5*-5* an enzyme extracted from the nucleus with urea which has a relatively high activity towards DNA hydroperoxide. The possible role of these enzymes in the detoxication of lipid and DNA hydroperoxides is discussed and it is pointed out that they may be important participants in mechanism for the repair of free-radical damage.     

Thymine hydroperoxide, a substrate for rat Se-dependent glutathione peroxidase and glutathione transferase isoenzymes

The thymine hydroperoxide, 5-hydroperoxymethyluracil, is a substrate for Se-dependent glutathione (GSH) peroxidase and the Se-independent GSH peroxidase activity associated with the GSH transferase fraction. These enzymes may contribute to repair mechanisms for damage caused by oxygen radicals. GSH transferases 1-1, 2-2, 3-3, 4-4, 6-6, and 7-7 [(1984) Biochem. Pharmacol. 33, 2539-2540] are shown to differ considerably in their ability to utilize this substrate. For example, high activity is found in GSH transferase 6-6 which is the major isoenzyme in spermatogenic tubules where DNA synthesis is so active and faithful DNA replication so important. The activity of the purified GSH transferase isoenzymes towards 5-hydroperoxymethyluracil is comparable with their activity towards other endogenous substrates related to cellular peroxidation such as linoleate hydroperoxide and 4-hydroxynon-2-enal or biologically important xenobiotic metabolites such as benzo(a)pyrene-7,8-diol-9,10-oxide.     

Cytosolic glutathione transferases from rat liver. Primary structure of class alpha glutathione transferase 8-8 and characterization of low-abundance class Mu glutathione transferases.

Six GSH transferases with neutral/acidic isoelectric points were purified from the cytosol fraction of rat liver. Four transferases are class Mu enzymes related to the previously characterized GSH transferases 3-3, 4-4 and 6-6, as judged by structural and enzymic properties. Two additional GSH transferases are distinguished by high specific activities with 4-hydroxyalk-2-enals, toxic products of lipid peroxidation. The most abundant of these two enzymes, GSH transferase 8-8, a class Alpha enzyme, has earlier been identified in rat lung and kidney. The amino acid sequence of subunit 8 was determined and showed a typical class Alpha GSH transferase structure including an N-acetylated N-terminal methionine residue.     

Structure and function of YghU, a nu-class glutathione transferase related to YfcG from Escherichia coli

The crystal structure (1.50 ? resolution) and biochemical properties of the GSH transferase homologue, YghU, from Escherichia coli reveal that the protein is unusual in that it binds two molecules of GSH in each active site. The crystallographic observation is consistent with biphasic equilibrium binding data that indicate one tight (K(d1) = 0.07 ± 0.03 mM) and one weak (K(d2) = 1.3 ± 0.2 mM) binding site for GSH. YghU exhibits little or no GSH transferase activity with most typical electrophilic substrates but does possess a modest catalytic activity toward several organic hydroperoxides. Most notably, the enzyme also exhibits disulfide-bond reductase activity toward 2-hydroxyethyl disulfide [k(cat) = 74 ± 6 s(-1), and k(cat)/K(M)(GSH) = (6.6 ± 1.3) × 10(4) M(-1) s(-1)] that is comparable to that previously determined for YfcG. A superposition of the structures of the YghU·2GSH and YfcG·GSSG complexes reveals a remarkable structural similarity of the active sites and the 2GSH and GSSG molecules in each. We conclude that the two structures represent reduced and oxidized forms of GSH-dependent disulfide-bond oxidoreductases that are distantly related to glutaredoxin 2. The structures and properties of YghU and YfcG indicate that they are members of the same, but previously unidentified, subfamily of GSH transferase homologues, which we suggest be called the nu-class GSH transferases.     

4-Hydroxy-2,3-trans-nonenal stimulates microsomal lipid peroxidation by reducing the glutathione-dependent protection

Glutathione (GSH) protects liver microsomes against lipid peroxidation. This is probably due to the reduction of vitamin E radicals by GSH, a reaction catalyzed by a membrane-bound protein. Pretreatment of liver microsomes with 0.1 or 1mM 4-hydroxy-2,3-trans-nonenal (HNE), a major product of lipid peroxidation, reduces the GSH-dependent protection. GSH and vitamin E concentrations are not affected by this pretreatment. Pretreatment with 0.1 mM N-ethyl maleimide (NEM), a synthetic sulfhydryl reagent, resulted in a reduction similar to that with HNE of the GSH-dependent protection against lipid peroxidation. The reduction of the GSH-dependent protection by HNE and NEM is probably the result of inactivation of the membrane-bound protein by covalent binding to an essential SH group on the protein. If the GSH-dependent protection would proceed via the microsomal GSH transferase, pretreatment with NEM, which activates the microsomal GSH transferase, should enhance the GSH-dependent protection. Actually a decrease in the GSH-dependent protection is found. Apparently the GSH-dependent protection does not proceed via the microsomal GSH transferase. Also the microsomal phospholipase A2 is not involved, since addition of 0.1 mM mepacrine, an inhibitor of phospholipase A2, did not preclude the GSH-dependent protection. Once the process of lipid peroxidation, either in vivo or in vitro, has started, the protection of liver microsomes by GSH is less effective. This might be the result of formed HNE. In this way an endproduct of lipid peroxidation stimulates the process that generates this product.     

Single-step purification and h.p.l.c. analysis of glutathione transferase 8-8 in rat tissues.

GSSG selectively elutes two GSH transferases from a mixture of rat GSH transferases bound to a GSH-agarose affinity matrix. One is a form of GSH transferase 1-1 and the other is shown to be GSH transferase 8-8. By using tissues that lack this form of GSH transferase 1-1 (e.g. lung), GSH transferase 8-8 may thus be purified from cytosol in a single step. Quantitative analysis of the tissue distribution of GSH transferase 8-8 was obtained by h.p.l.c.     

The protective action of glutathione on the microbial mutagenicity of the Z- and E-isomers of 1,3-dichloropropene

The Z(cis)- and E(trans)-isomers of 1,3-dichloropropene (DCP), in confirmation of previous reports, caused dose-dependent increases in the numbers of reverse mutations in Salmonella typhimurium TA100 in the presence and absence of a 9000 X g supernatant fraction (S9) from the livers of Aroclor-treated rats. The relevance of these findings to mammals is uncertain, not least because of major differences in the metabolism of the DCPs in the microbial assay systems and in vivo. For example, (Z)-DCP is efficiently detoxified in mammals by the operation of a glutathione (GSH)-dependent S-alkyl transferase. It is possible that such detoxification could proceed only very slowly in the microbial assays because the concentrations of GSH could be severely rate-limiting even in those assays fortified by the addition of S9. The results obtained in the current study demonstrate a dramatic reduction in the microbial mutagenicity of both (Z)- and (E)-DCP when the concentration of GSH in the microbial assays was adjusted to a normal physiological concentration (5 mM). However, this protective action of GSH was at least as effective in the absence of S9 as in its presence, suggesting that it was not mediated by mammalian GSH transferase. There appears to be little or no GSH alkyl or aryl transferase in the cytosol of S. typhimurium TA100, but intracellular GSH is present at a concentration similar to that found in mammalian cells. Since the uncatalysed reaction between the DCPs and glutathione is relatively slow, the effect is not due simply to their destruction by GSH. It is possible that a physiological concentration of extracellular GSH maintains the intracellular GSH in a reduced form in which its nucleophilic thiol group competes effectively with the nucleophilic centres in the bacterial DNA for the haloalkenes. The current results highlight the efficiency of GSH-linked systems in affording protection against the genotoxic action of the DCPs. It may be presumed that their operation would exert a major limiting effect on the genotoxicity of (Z)- and (E)-DCP in mammals.     

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

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

Glutathione transferase P1‐1 as an arsenic drug‐sequestering enzyme

Arsenic‐based compounds are paradoxically both poisons and drugs. Glutathione transferase (GSTP1‐1) is a major factor in resistance to such drugs. Here we describe using crystallography, X‐ray absorption spectroscopy, mutagenesis, mass spectrometry, and kinetic studies how GSTP1‐1 recognizes the drug phenylarsine oxide (PAO). In conditions of cellular stress where glutathione (GSH) levels are low, PAO crosslinks C47 to C101 of the opposing monomer, a distance of 19.9 Å, and causes a dramatic widening of the dimer interface by approximately 10 Å. The GSH conjugate of PAO, which forms rapidly in cancerous cells, is a potent inhibitor (K_i = 90 nM) and binds as a di‐GSH complex in the active site forming part of a continuous network of interactions from one active site to the other. In summary, GSTP1‐1 can detoxify arsenic‐based drugs by sequestration at the active site and at the dimer interface, in situations where there is a plentiful supply of GSH, and at the reactive cysteines in conditions of low GSH.     

The time course of effects of cadmium and 3-methylcholanthrene on activities of enzymes of xenobiotic metabolism and metallothionein levels in the plaice, Pleuronectes platessa

Plaice were treated with an acute dose of a polyaromatic hydrocarbon (3-methylcholanthrene, 3-MC) or cadmium, or 3-MC and cadmium by i.p. injection. The effects on hepatic detoxication systems, cytochrome P-450 (ethoxyresorufin O-deethylase, EROD), UDP-glucuronyl transferase, glutathione S-transferase, glutathione peroxidase activities, total glutathione (GSH), metallothionein and Cd and Zn in the cytosol were studied over a 14 day period. 3-MC increased EROD (7-18-fold), glucuronyl transferase (40%) and GSH transferase (200%) activities, whereas GSH peroxidase activity decreased by 60%. Cd treatment inhibited EROD (90%), GSH transferase (90%) and GSH peroxidase (30%) activities and displaced Zn. Total GSH levels increased (200%) prior to onset of metallothionein synthesis (6 days). Cotreatment with 3-MC and Cd led to a marked increase in GSH levels (300%) but the onset of metallothionein synthesis was delayed by a week. Induction of enzyme activities was abolished, EROD activity was strongly inhibited and there was a transient 50-90% decrease in glucuronyl transferase, GSH transferase and GSH peroxidase activities on days 2 and 3 after treatment. The results indicate that a polyaromatic hydrocarbon could result in increased peroxidative damage, the heavy metal Cd can severely inhibit organic xeno- and endobiotic metabolism and that the effects of both agents may be synergistic.     

Studies on the activity and activation of rat liver microsomal glutathione transferase with a series of glutathione analogues

The substrate specificity of rat liver microsomal glutathione transferase toward glutathione has been examined in a systematic manner. Out of a glycyl-modified and eight gamma-glutamyl-modified glutathione analogues, it was found that four (glutaryl-L-Cys-Gly, alpha-L-Glu-L-Cys-Gly, alpha-D-Glu-L-Cys-Gly, and gamma-L-Glu-L-Cys-beta-Ala) function as substrates. The kinetic parameters for three of these substrates (the alpha-D-Glu-L-Cys-Gly analogue gave very low activity) were compared with those of GSH with both unactivated and the N-ethylmaleimide-activated microsomal glutathione transferase. The alpha-L-Glu-L-Cys-Gly analogue is similar to GSH in that it has a higher kcat (6.9 versus 0.6 s-1) value with the activated enzyme compared with the unactivated enzyme but displays a high Km (6 versus 11 mM) with both forms. Glutaryl-L-Cys-Gly, in contrast, exhibited a similar kcat (8.9 versus 6.7 s-1) with the N-ethylmaleimide-treated enzyme but retains a higher Km value (50 versus 15 mM). Thus, the alpha-amino group of the glutamyl residue in GSH is important for the activity of the activated microsomal glutathione transferase. These observations were quantitated by analyzing the changes in the Gibbs free energy of binding calculated from the changes in kcat/Km values, comparing the analogues to GSH and each other. It is estimated that the binding energy of the alpha-amino group of the glutamyl residue in GSH contributes 9.7 kJ/mol to catalysis by the activated enzyme, whereas the corresponding value for the unactivated enzyme is 3.2 kJ/mol. The importance of the acidic functions in glutathione is also evident as shown by the lack of activity with 4-aminobutyric acid-L-Cys-Gly and the low kcat/Km values with gamma-L-Glu-L-Cys-beta-Ala (0.03 and 0.01 mM-1s-1 for unactivated and activated enzyme, respectively). Utilization of binding energy from a correctly positioned carboxyl group in the glycine residue (10 and 17 kJ/mol for unactivated and activated enzyme, respectively) therefore also appears to be required for optimal activity and activation. A conformational change in the microsomal glutathione transferase upon treatment with N-ethylmaleimide or trypsin, which allows utilization of binding energy from the alpha-amino group of GSH as well as the glycine carboxyl in catalysis, is suggested to account for at least part of the activation of the enzyme.     

Adaptation of microsomal glutathione transferase 1 in PC12 cells with modified PMCA isoforms composition

Microsomal glutathione transferase 1 (MGST1) is an integral homo-trimeric membrane protein with transferase and peroxidase activities. With glutathione as a co-substrate, it scavenges toxic compounds and may exert anti-apoptotic effect. We examined the effect of suppression of plasma membrane Ca(2+)-ATPase isoforms--PMCA2 or PMCA3 on MGST1 in PC12 cells. GSH level was significantly higher in PMCA2-reduced line, but similar GSSG/GSH ratios in all cell lines suggested an efficient protection or absence of oxidative stress. The ATP concentration decreased in both modified lines, although in PMCA2-suppressed cells the decrease was higher. Total GSTs activity in postmitochondrial fraction increased by 30% in the cells with reduced PMCA3. After treatment with MGST1 activator N-ethylmaleimide (NEM), the activity increased in both transfected lines by 30-40%. Real-time PCR also showed a higher mRNA expression of MGST1 in these lines. Staining with antibody recognizing all cytosolic and membrane-bound GSTs revealed the difference in oligomeric forms of GSTs, and specific anti-MGST1 antibody showed the presence of MGST1 hexamers in the transfected cells. Formation of similar hexamers was detected in the control line after treatment with peroxynitrite. Modification of MGST1 under reduced PMCAs amount may represent an adaptive mechanism that offers protection against the cytotoxicity mediated by increased Ca2+.     

Stereoselectivity of rat liver glutathione transferase isoenzymes for alpha-bromoisovaleric acid and alpha-bromoisovalerylurea enantiomers.

The stereoselectivity of purified rat GSH transferases towards alpha-bromoisovaleric acid (BI) and its amide derivative alpha-bromoisovalerylurea (BIU) was investigated. GSH transferase 2-2 was the only enzyme to catalyse the conjugation of BI and was selective for the (S)-enantiomer. The conjugation of (R)- and (S)-BIU was catalysed by the isoenzymes 2-2, 3-3 and 4-4. Transferase 1-1 was less active, and no catalytic activity was observed with transferase 7-7. Isoenzymes 1-1 and 2-2 of the Alpha multigene family preferentially catalysed the conjugation of the (S)-enantiomer of BIU (and BI), whereas isoenzymes 3-3 and 4-4 of the Mu multigene family preferred (R)-BIU. The opposite stereoselectivity of conjugation of BI and BIU previously observed in isolated rat hepatocytes and the summation of activities of enzymes known to be present in hepatocytes on the basis of present data are in accord.     

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.     

H.p.l.c. separation and study of the charge isomers of human placental glutathione transferase.

Glutathione transferase (GST) from human placenta was purified by affinity chromatography and anion-exchange h.p.l.c. The enzyme exhibited different chromatographic and electrophoretic behaviours according to the concentration of GSH, suggesting a possible change in the net charge of the molecule and a concomitant conformational change due to ligand binding. Two interconvertible forms were quantitatively separated into distinct catalytically active states by h.p.l.c. Depending upon the GSH concentration, polyacrylamide-gel electrophoresis revealed the presence of one or two bands. A Kd of 0.42 mM for GSH was determined fluorimetrically. The loss in intrinsic fluorescence also suggested a conformational change in the enzyme. Kinetic studies using ethacrynic acid were conducted to determine whether the presumed conformational change could effect the catalytic capability of placental GST. A biphasic response in initial velocities was observed with increasing concentrations of GSH. Two apparent Km values of 0.38 and 50.27 mM were obtained for GSH, whereas Vmax. values showed a 46-fold difference. It was concluded that the enzyme assumes a highly anionic form in the presence of a low GSH concentration, whereas it is converted into relatively weaker anionic form when its immediate environment contains a high GSH concentration. Since the average tissue concentration of total GSH was estimated at 0.11 mM for term placenta, the results suggest that the high-affinity-low-activity conformer would predominate in vivo.