Plant phenols as in vitro inhibitors of glutathione S-transferase(s)

Ellagic acid, a commonly occurring plant phenol, was shown to be a potent in vitro inhibitor of GSH-transferase(s) activity. Other plant phenols such as ferrulic acid, caffeic acid and chlorogenic acid also showed a concentration dependent inhibition of GSH-transferase(s) activity. The I50 values of ellagic acid, caffeic acid, chlorogenic acid and ferrulic acid were 8.3 X 10(-5)M, 14.0 X 10(-5)M, 20.0 X 10(-5)M and 22.0 X 10(-5)M respectively, suggesting that ellagic acid is the most potent inhibitor of all the four studied plant phenols. At 55 microM concentration of ellagic acid, a significant inhibition (35-47%) was observed on GSH-transferase activity towards CDNB, p-nitrobenzyl chloride and 1,2-epoxy-3-(p-nitrophenoxy)propane as substrates. Ellagic acid inhibited GSH-transferase(s) activity in a non-competitive manner with respect to CDNB while with respect to GSH it inhibited the enzyme activity in a competitive manner. Other phenolic compounds purpurogallin , quercetin, alizarin and monolactone also showed a concentration dependent inhibition of the enzyme activity with a I50 of 0.8 X 10(-5)M, 1.0 X 10(-5)M, 8.0 X 10(-5)M and 16.0 X 10(-5)M respectively. These inhibitors of GSH-transferase(s) activity should be useful in studying the in vitro enzyme mediated reactions of exogenous and endogenous compounds.     

Differences in the occurrence of glutathione transferase isoenzymes in rat lung and liver

Cytosolic GSH transferases have been purified from rat lung by affinity chromatography followed by chromatofocusing. On the criteria of order of elution, substrate specificity, apparent subunit Mr, sensitivity to inhibitors, and reaction with antibodies, transferase subunits equivalent to subunits 2, 3, and 4, in the binary combinations occurring in liver, were identified. However, subunit 1 (and therefore transferases 1-1 and 1-2) was not detected. The most conspicuous difference is the presence in lung of a new form, eluting at pH 8.7, which is not detected in rat liver. This isoenzyme (transferase "pH 8.7") is characterized by its low apparent subunit Mr and high efficiency in the conjugation of glutathione with anti-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide, considered the ultimate carcinogen of benzo(a)-pyrene.     

Glutathione and glutathione S-transferases in the salmonella mammalian-microsome mutagenicity test

Levels of the tripeptide glutathione (GSH) and the activity of glutathione S-transferases were investigated in S9 fractions of rats and mice and in Salmonella typhymurium tester strains TA1535, TA100, TA1538 and TA98. The S9 and Salmonella typhimurium tester strains had high levels of glutathione. Compared with S9, the activity of GSH S-transferases was lower in the bacteria. However, electrophiles such as 1-chloro-2,4-dinitrobenzene (CDNB), diethyl maleate and styrene oxide were effectively bound to bacterial GSH.

The mutagenicity of the direct mutagen CDNB was drastically lowered in presence of S9 fractions but not in presence of microsomes. A comparable decrease was obtained when microsomal supernatant, which contains GSH and GSH S-transferases, was added to the microsomes. Addition of GSH in excess completely abolished mutagenicity of CDNB. These results demonstrate that the conjugation of electrophiles with GSH mediated by the S9 fraction or the bacterial tester strains represents an important detoxication mechanism which may influence the results obtained with the Salmonella typhimurium mammalian-microsome mutagenicity test.     

The interactions of triethyltin with rat glutathione-S-transferases A, B and C. Enzyme-inhibition and equilibrium-dialysis studies.

Purified glutathione(GSH)-S-transferases A, B and C from rat liver are inhibited by triethyltin (SnEt3). With 1-chloro-2,4-dinitro benzene (CDNB) as the limiting substrate the inhibition is competitive in each case. At a GSH concentration of 5 . 10(-3) M the inhibition constants for transferases A and C at 25 degrees C are similar and very low, 3.2 . 10(-8) M and 5.6 . 10(-8) M respectively, whereas for transferase B the inhibition constant is 3.5 . 10(-5) M. Equilibrium-dialysis experiments carried out at 4 degrees C in the absence of GSH give apparent dissociation constants of 7.1 . 10(-4) M and 3.4 . 10(-4) M for transferases A and B respectively, but if 5 . 10(-3) M glutathione is included in the dialysis solutions these values fall to 2.0 . 10(-7) M and 2.6 . 10(-5) M, which are within an order of magnitude of the kinetic Ki-values. Chromatographic experiments with Sephadex G-10 show that GSH and SnEt3 interact in aqueous solution under the conditions of the enzyme-kinetic and equilibrium-dialysis experiments. It is suggested that the inhibited enzymes are in the form of ternary complexes, enzyme-GSH-SnEt3, in which GSH and SnEt3 may or may not interact directly; or are possibly quaternary complexes, enzyme-(GSH)2-SnEt3. SnEt3 could be valuable as a selective inhibitor of transferases A and C in mixtures of the three transferases.     

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.     

Mutagenicity of 1-fluoro-2,4-dinitrobenzene is affected by bacterial glutathione

Recently we have shown that Salmonella typhimurium tester strains have high levels of the tripeptide glutathione (GSH) and activity of GSH S-transferases (Summer et al., 1979). In continuation of the GSH-dependent suppression of mutagenicity of 1-chloro-2,4-dinitrobenzene in presence of S9 fraction (Summer et al., 1979), this paper is focused on the GSH-dependent detoxifying capacity of the bacterial tester strains. 1-Fluoro-2,4-dinitrobenzene (FDNB), an electrophilic agent, which is used to identify terminal amino acids in proteins (Sanger reagent), readily reacts with GSH leading to a dose-dependent depletion of bacterial GSH. Additionally, FDNB is a strong mutagen for Salmonella typhimurium TA100, TA1538 and TA98 without metabolic activation.Presumably owing to conjugation with bacterial GSH, FDNB in concentrations which were lower or equal to those of bacterial GSH were found to be not mutagenic. Accordingly, increasing amounts of bacteria in the test system require increasing amounts of FDNB for expression of mutagenicity.     

Activation of microsomal glutathione S-transferase activity by sulfhydryl reagents.

Rat liver microsomes exhibit glutathione S-transferase activity with 1-chloro-2,4-dinitrobenzene as the second substrate. This activity can be stimulated 8-fold by treatment of the microsomes with N-ethylmaleimide and 4-fold with iodoacetamide. The corresponding glutathione S-transferase activity of the supernatant fraction is not affected by such treatment. These findings suggest that rat liver microsomes contain glutathione S-transferase distinct from those found in the cytoplasmic and that the microsomal transferase can be activated by modification of microsomal sulfhydryl group(s).     

Asn112 in Plasmodium falciparum glutathione S-transferase is essential for induced reversible tetramerization by phosphate or pyrophosphate

The glutathione S-transferase from Plasmodium falciparum presents distinct features which are absent from mammalian GST isoenzyme counterparts. Most apparent among these are the ability to tetramerize and the presence of a flexible loop. The loop, situated between the 113–119 residues, has been reported necessary for the tetramerization process. In this article, we report that a residue outside of this loop, Asn112, is a key to the process — to the point where the single Asn112Leu mutation prevents tetramerization altogether. We propose that a structural pattern involving the interaction of the Asn112 and Lys117 residues from two neighboring subunits plays a role in keeping the tetramer structure stable. We also report that, for the tetramerization of the wild-type PfGST to occur, phosphate or pyrophosphate anions must be present. In other words, tetramerization is a phosphate- or pyrophosphate-induced process. Furthermore, the presence of magnesium reinforces this induction. We present experimental evidence for these claims as well as a preliminary calorimetric and kinetic study of the dimeric Asn112Leu PfGST mutant. We also propose a putative binding site for phosphate or pyrophosphate anions through a comparative structural analysis of PfGST and pyrophosphatases from several organisms. Our results highlight the differences between PfGST and the human isoenzymes, which make the parasite enzyme a suitable antimalarial target.     

Evidence for glutathione peroxidase activities in cultured plant cells

Extracts from cultured plant cells of spinach, maize and sycamore and from Lemna plants contain detectable glutathione peroxidase activity, using either hydrogen peroxide or t-butyl hydroperoxide as substrates. Using extracts from cultured maize cells, two peaks of glutathione peroxidase activity could be resolved by a combination of gel filtration and ion exchange chromatography. One peak was eluted along with glutathione transferase activity; the second was distinct from both glutathione transferase and ascorbic acid peroxidase, and was active with both hydrogen peroxide and organic hydroperoxides. It seems likely that at least two enzymes with glutathione peroxidase activity exist in higher plant cells.     

Expression of ligandin and glutathione S-transferase activities by cells in tissue culture.

A wide distribution of glutathione S-transferase activity towards 1-chloro-2,4-dinitrobenzene and 1,2-dichloro-4-dinitrobenzene has been detected in a range of non-transformed, transformed and hybrid cell lines. The levels of transferase activity are lower in these $\text{in vitro}$ cell lines than are corresponding $\text{in vivo}$ levels. A majority of the cell lines tested contain proteins that are antigenically related to rat liver glutathione S-transferase B (ligandin).     

Glutathione S-transferase activities in rat and mouse sperm and human semen

Glutathione $\text{S}$-transferase activity was found in sperm of the rat and $\text{DBA}\text{2J}$ and C57 $\text{BL}\text{6J}$ mice. In rat sperm activities with benzo(a)pyrene 4,5-oxide, styrene 7,8-oxide, and 1-chloro-2,4-dinitrobenzene were 0.88, 1.07, and 26.1 nmoles/min/mg protein, respectively. Δ⁵-3-Ketosteroid isomerase activity of rat sperm was 4.9 nmoles/min/mg protein. These specific glutathione $\text{S}$-transferase and Δ⁵-3-ketosteroid isomerase activities in sperm represent 0.4–4.1% of rat liver cytosol values. Human semen also contained significant glutathione $\text{S}$-transferase activity. It is postulated that these enzymes could function in the metabolism and detoxification of certain electrophilic xenobiotics, if present in sperm.     

Dietary administration of 2(3)-t-butyl-4-hydroxyanisole elevates mouse liver microsome-mediated DNA binding and mutagenicity of aflatoxin B1

Administration of the phenolic antioxidant 2(3)-t-butyl-4-hydroxyanisole (BHA) to mice resulted in a 2-3-fold increase in the liver microsome catalyzed irreversible binding of aflatoxin B1 (AFB1) to calf thymus DNA and up to a 5-fold increase in the ability to induce mutations in Salmonella typhimurium TA98. Maximum induction of AFB1 binding to DNA occurred after 2 days of BHA administration whereas cytosolic glutathione S-transferase was maximally induced (6-fold) only after 10 days of BHA feeding. The induction of a new cytochrome P-450 species was indicated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and an enhanced sensitivity to inhibition by metyrapone and alpha-naphthoflavone. Addition of control cytosol (containing glutathione S-transferase) + glutathione to control microsomes decreased AFB1 binding to DNA by 26%. However, replacement of control cytosol by BHA cytosol which contained 6 times more glutathione S-transferase only marginally enhanced the inhibition to 38%. These data suggest that BHA may exert its effect in the liver primarily through an alteration of the cytochrome P-450 dependent activation process although an increase in the conjugation of reactive metabolite may play a contributory role.     

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.     

Crystallographic survey of active sites of an unclassified glutathione transferase from Bombyx mori

Background

Glutathione transferase (GST) catalyzes a major step in the xenobiotic detoxification pathway. We previously identified a novel, unclassified GST that is upregulated in an insecticide-resistant silkworm (Bombyx mori) upon insecticide exposure. Here, we sought to further characterize this GST, bmGSTu, by solving and refining its crystal structure and identifying its catalytic residues.

Methods

The structure of wild-type bmGSTu was determined with a resolution of 2.1 Å by synchrotron radiation and molecular modeling. Potential catalytic residues were mutated to alanine by means of site-directed mutagenesis, and kinetic data determined for wild-type and mutated bmGSTu.

Results

We found that bmGSTu occurred as a dimer, and that, like other GSTs, each subunit displayed a G-site and an H-site in the active center. Bound glutathione could be localized at the G-site. Kinetic data of the mutated forms of bmGSTu show that Val55, Glu67, and Ser68 in the G-site are important for catalysis. Furthermore, the H-site showed some unique features.

Conclusions

This is the first study to our knowledge to elucidate the molecular conformation of this B. mori GST. Our results indicate that residues Val55, Glu67, and Ser68, as well as Tyr7 and Ser12, in the glutathione-binding region of bmGSTu are critical for catalytic function.

General Significance

Our results, together with our previous finding that bmGSTu was preferentially induced in an insecticide-resistant strain, support the idea that bmGSTu functions in the transformation of exogenous chemical agents. Furthermore, the unique features observed in bmGSTu may shed light on mechanisms of insecticide resistance.     

Measurement of drug-metabolizing systems in Salmonella typhimurium strains G46, TA1535, TA100, TA1538 and TA98

Salmonella typhimurium strains which are commonly used in the Ames test for screening potential carcinogens were examined for a number of drug-metabolizing systems. Neither cytochrome P-450 itself nor two activities catalyzed by the cytochrome P-450 system in mammalian cells, i.e., benzpyrene monooxygenase and ethoxycoumarin O-deethylation, could be detected. Nor do these bacterial strains demonstrate any ability to detoxify epoxides by hydrating them or to conjugate p-nitrophenol with glucuronic acid.On the other hand, S. typhimurium strains G46, TA1535, TA100, TA1538 and TA98 contain considerable amounts of acid-soluble thiols, approx. 5–10% of which is glutathione. These bacteria can also enzymatically conjugate glutathione with 1-chloro-2,4-dinitrobenzene (CDNB) and can reduce oxidized glutathione using NADPH as cofactor.Thus, enzymatic and non-enzymatic reaction of immediate carcinogens with thiol groups in S. typhimurium may have a significant effect on the outcome of the Ames test in certain cases.     

Synthesis,characterization and fluorescent properties of cerium(III) glutathione complex

The cerium (III) glutathione complex was synthesized by the redox reaction of cerium (IV) with glutathione reduced (GSH) in aqueous solution. The Job‐plots indicate an ML (L = GSSG) stoichiometry of the complex. The fluorescent properties of the compound were investigated. The as‐prepared complex showed the characteristic maximum emission spectra of Ce(III) at 350 nm (λ_ex = 255 nm). The fluorescence results show that the Ce(IV) ions are first reduced to Ce(III), and then form Ce(III) complex after reacting with GSH. The complex was characterized by element analysis and FT‐IR spectra; the stability of the complex was analyzed by cyclic voltammeters and DSC‐TG as well. Finally, Ce(IV) was successfully employed to determine the concentrations of GSH in the presence of GSSG, in which the fluorescence intensities are proportional to the concentrations of GSH in the range of 1–100 nM with the detection limit of 0.05 nM of GSH, without interference from the presence of GSSG. Copyright © 2009 John Wiley & Sons, Ltd.     

Mutagenic activity of the glutathione S-transferase substrate 1-chloro-2,4-dinitrobenzene (CDNB) in the Salmonella mutagenicity assay

The mutagenicity of the commonly used glutathione S-transferase substrates 1-chloro-2,4-dinitrobenzene (CDNB) and 1,2-dichloro-4-nitrobenzene (DCNB) was investigated in the Salmonella mutagenicity assay. CDNB induced a concentration-dependent mutagenic response in Salmonella typhimurium strain TA98. Incorporation of an activation system derived from Aroclor 1254-induced rats did not influence mutagenic response. Under the same conditions DCNB failed to display mutagenic activity. The mutagenic activity of CDNB was attenuated in bacterial strains under-expressing nitroreductase or O-acetylase activity but, in contrast, it was exaggerated in an O-acetylase over-expressing strain. It is inferred that CDNB exhibits a mutagenic response following reduction of the nitro-group to the hydroxylamine, which is further acetylated to form the acetoxy derivative that presumably breaks down spontaneously to generate the nitrenium ion, the likely ultimate mutagen.     

Investigation of the role of conserved residues Ser13, Asn48 and Pro49 in the catalytic mechanism of the tau class glutathione transferase from Glycine max

Plant glutathione transferases (GSTs) play a key role in the metabolism of various xenobiotics. In this report, the catalytic mechanism of the tau class GSTU4-4 isoenzyme from Glycine max (GmGSTU4-4) was investigated by site-directed mutagenesis and steady-state kinetic analysis. The catalytic properties of the wild-type enzyme and three mutants of strictly conserved residues (Ser13Ala, Asn48Ala and Pro49Ala) were studied in 1-chloro-2,4-dinitrobenzene (CDNB) conjugation reaction. The results showed that the mutations significantly affect substrate binding and specificity. The effect of Ser13Ala mutation on the catalytic efficiency of the enzyme could be explained by assuming the direct involvement of Ser13 to the reaction chemistry and the correct positioning of GSH and CDNB in the ternary catalytic complex. Asn48 and Pro49 were found to have a direct role on the structural integrity of the GSH-binding site (G-site). Moreover, mutation of Asn48 and Pro49 residues may bring about secondary effects altering the thermal stability and the catalytic activity (k_cat) of the enzyme without affecting the nature of the rate-limiting step of the catalytic reaction.     

Plasmodium vivax: molecular cloning, expression and characterization of glutathione S-transferase

Malaria parasite glutathione S-transferases (GSTs) are postulated to be essential for parasite survival by protecting the parasite against oxidative stress and buffering the detoxification of heme-binding compounds; therefore, GSTs are considered potential targets for drug development. In this study, we identified a Plasmodium vivax gene encoding GST (PvGST) and characterized the biochemical properties of the recombinant enzyme. The PvGST contained 618 bp that encoded 205 amino acids and shared a significant degree of sequence identity with GSTs from other Plasmodium species. The recombinant homodimeric enzyme had an approximate molecular mass of 50kDa and exhibited GSH-conjugating and GSH-peroxidase activities towards various model substrates. The optimal pH for recombinant PvGST (rPvGST) activity was pH 8.0, and the enzyme was moderately unstable at 37 degrees C. The K(m) values of rPvGST with respect to GSH and CDNB were 0.17+/-0.09 and 2.1+/-0.4mM, respectively. The significant sequence homology and similar biochemical properties of PvGST and Plasmodium falciparum GST (PfGST) indicate that they may have similar molecular structures. This information may be useful for the design of specific inhibitors for plasmodial GSTs as potential antimalarial drugs.