Human Glutathione S-transferase Isoenzymes Research Articles

Quantitative Differences in the Active-Site Hydrophobicity of Five Human GlutathioneS-Transferase Isoenzymes: Water-Soluble Carcinogen-Selective Properties of the Neoplastic GSTP1-1 Species

The active-site (the H-site) hydrophobicity of five human glutathioneS-transferases (GSTs) was analyzed by application of linear free energy relationships (LFERs) with a series of S-alkylated glutathione inhibitors, GS(CH2)n− 1CH3(n= 1–14). Distinct linear reltionships were observed in the plots of logKi(inhibition constant) vsnfor the five forms, whereby theKis varied by three to four orders of magnitude. Mean free enthalpy changes per methylene group (−ΔΔG°s), a measure of H-site hydrophobicity, were in the order M1-1 (4.6 kJ/mol) > A1-1 (3.9 kJ/mol) > A1-2 (3.8 kJ/mol) > A2-2 (2.8 kJ/mol) > P1-1 (1.6 kJ/mol). The quantitative differences may in part account for the extraordinary broad and overlapping substrate specificities of the Alpha-, Mu-, and Pi-class isoenzymes. In contrast to the Alpha and Mu classes being selective for strongly electrophilic compounds, the neoplastic P1-1 species was indicated to be selective for weakly electrophilic and water-soluble carcinogens such as acrolein and hydroxyalkenals.

Inhibition of glutathione conjugation in the rat in vivo by analogues of glutathione conjugates

Glutathione (GSH) conjugation plays an important role in (de-)toxification of its substrates in vivo. We have developed inhibitors of GSH conjugation that are active in the rat in vivo which are derived from the structure of GSH conjugates: they contain a backbone of γ- l-Glu- d-2-aminoadipic acid that is virtually isosteric with the γ- l-Glu- l-Cys-Gly structure of GSH. In addition, a hydrophobic alkyl group is attached such that it may interact with the H-site of the enzyme. Finally, the carboxyl groups were esterified with alcohols of varying chain length. The results show that all these compounds preferentially inhibit α-GST′s 1-1 and 2-2, have less effect on μ isoenzymes 3-3 and 4-4, and finally, have little effect on rat θ (G.J. Mulder, S. Ouwerkerk-Mahadevan, Modulation of glutathione conjugation in vivo: How to decrease glutathione conjugation in vivo or in intact cellular systems in vitro, Chem. Biol. Interact. 105 (1997) 17–34) and π (S. Ouwerkerk-Mahadevan, J.H. van Boom, M.C. Dreef-Tromp, J.H.T.M. Ploemen, D.J. Meyer, G.J. Mulder, Glutathione analogues as novel inhibitors of rat and human glutathione S-transferase isoenzymes, as well as of glutathione conjugation in isolated rat hepatocytes and the rat in vivo, Biochem. J., 308 (1995) 283–290). Several of the compounds inhibit the GSH conjugation of bromsulfophthalein and ( S)-2-bromisovalerylurea in hepatocytes, in the in situ recirculating rat liver perfusion and in the rat in vivo (after i.v. administration). The most effective compound contains a 2-heptylamine group linked as an amide to the 1-carboxyl group of the aminoadipic acid moiety at the H-site, and an ethyl ester at the 5-carboxylic acid group of aminoadipic acid.

In vitro inhibition of rat and human glutathione S-transferase isoenzymes by disulfiram and diethyldithiocarbamate

The drug disulfiram (DSF, Antabuse ®) has been used in the therapy of alcohol abuse. It is a potent inhibitor of aldehyde dehydrogenase. Its reduced form, diethyldithiocarbamate (DDTC), and further metabolites show similar activities. DSF and DDTC have also been widely used to inhibit mixed-function oxidases. In this study, the reversible inhibition and time-dependent inactivation of the major rat and human glutathione S-transferase (GST) isoenzymes by DSF and DDTC was investigated. Reversible inhibition, using 1-chloro-2,4-dinitrobenzene as substrate for the GST alpha-, mu-, and pi-class, expressed as I 50 (in μM), ranged from 5–18 (human A1-1), 43–57 (rat 4-4) and 66–83 (rat 1-1), for both DSF and DDTC. The I 50 for rat GST theta, using 1,2-epoxy-3-(p-nitrophenoxy)-propane as substrate, was 350 μM for DDTC. The other GSTs were significantly less sensitive to inhibition. The major part of reversible inhibition by DSF was shown to be due to DDTC, formed rapidly upon reduction of DSF by the glutathione (GSH) present in the assay to measure GST activity. The oxidized GSH formed upon reduction of DSF might also have made a minor contribution to reversible inhibition. The rat and human pi-class was, by far, the most sensitive class for time-dependent inactivation by DSF, but no such inactivation was observed for any of the GSTs by DDTC. Moderate susceptibility to inactivation by DSF of all the other GSTs was observed, except for human A2-2, which does not possess a cysteine residue. Consistent with the assumption that a thiol residue is involved in this inactivation, a significant part of the activity could be restored by treatment of the inactivated GST with GSH or dithiotreitol.

Glutathione analogues as novel inhibitors of rat and human glutathione S-transferase isoenzymes, as well as of glutathione conjugation in isolated rat hepatocytes and in the rat in vivo

Inhibitors of rat and human Alpha- and Mu-class glutathione S-transferases that effectively inhibit the glutathione (GSH) conjugation of bromosulphophthalein in the rat liver cytosolic fraction, isolated rat hepatocytes and in the rat liver in vivo have been developed. The GSH analogue (R)-5-carboxy-2-gamma-(S)-glutamylamino-N-hexylpentamide [Adang, Brussee, van der Gen and Mulder (1991) J. Biol. Chem. 266, 830-836] was used as the lead compound. To obtain more potent inhibitors, it was modified by replacement of the N-hexyl moiety by N-2-heptyl and by esterification of the 5-carboxy group with ethyl and dodecyl groups. In isolated hepatocytes, the branched N-2-heptyl derivatives were stronger inhibitors of GSH conjugation of bromosulphophthalein than the N-hexyl derivatives. The ethyl ester compounds were more efficient than the corresponding unesterified derivatives. The dodecyl ester of the N-2-heptyl analogue was the most effective inhibitor in isolated hepatocytes, but was relatively toxic in vivo. However, the corresponding ethyl ester was a potent in vivo inhibitor: GSH conjugation of bromosulphophthalein (as assessed by biliary excretion of the conjugate) was decreased by 70% after administration of a dose of 200 mumol/kg. The isoenzyme specificity of the inhibitors towards purified rat and human glutathione S-transferases was also examined. The unesterified compounds were more potent than the esterified analogues, and inhibited Alpha- and Mu-class isoenzymes of both rat and human glutathione S-transferase (Ki range 1-40 microM). Other GSH-dependent enzymes, i.e. GSH peroxidase, GSH reductase and gamma-glutamyltranspeptide, were not inhibited. Thus (R)-5-ethyloxycarbonyl-2-gamma-(S)-glutamylamino-N-2-hept ylpentamide, the in vivo inhibitor of GSH conjugation, may be useful in helping to assess the role of the Alpha and Mu classes of glutathione S-transferases in cellular biochemistry, physiology and pathology.

Stereoselectivity of human liver and intestinal cytosolic fractions as well as purified human glutathione S-transferase isoenzymes towards 2-bromoisovalerylurea enantiomers

Glutathione (GSH) conjugation of 2-bromoisovalerylurea (BIU) enantiomers is stereoselective in humans in vivo. Administration of racemic BIU results in a higher plasma elimination and urinary excretion of R-BIU and its mercapturate, respectively, than of S-BIU and its mercapturate. In order to relate the in vivo BIU pharmacokinetics to the activity of glutathioe S-transferase (GST) isoenzymes, the GSH conjugation of BIU enantiomers was studied with human liver and intestinal cytosolic fractions as well as purified human class alpha (GSTA1-1, GSTA2-2), mu (GSTM1a-1a) and pi (GSTP1-1) GST isoenzymes. Stereoselective GSH conjugation of BIU enantiomers was observed for most human liver and intestinal cytosolic fraction. In general, the cytosolic fractions preferentially conjugated S-BIU. Stereoselective preference for GSH conjugation of S-BIU was also observed for GSTA2-2 and GSTM1a-1a, whereas GSTA1-1 was not selective for either of the BIU enantiomers. GSTP1-1 did not catalyse conjugation of R- and S-BIU. Quantification of the GST isoenzymes in the liver cytosolic fractions showed that the stereoselectivity towards S-BIU was related to the profile and amount of GST subunits in the cytosolic fractions. The discrepancy in stereoselectivity between the BIU pharmacokinetics in vivo and the GSH conjugation of BIU enantiomers in vitro is discussed. In addition, since in contrast to human GSTM1a-1a, rat class Mu isoenzymes prefer R-BIU, the present results indicate that related isoenzymes in different species may have a different stereoselectivity.

Irreversible inhibition of human glutathione S-transferase isoenzymes by tetrachloro-1,4-benzoquinone and its glutathione conjugate

The quinones tetrachloro-1,4-benzoquinone (1,4-TCBQ) and its glutathione conjugate (GS-1,4-TCBQ) are potent irreversible inhibitors of most human glutathione S-transferase (GST) isoenzymes. Human π, ψ and μ are almost completely inhibited at a molar ratio 1,4-TCBQ/GST = 2 1 . The isoenzyme B1B1 was inhibited up to 75%, and higher concentrations (1,4-TCBQ/GST) = 6 1 ) were needed to reach this maximum effect. For these isoenzymes 75–85% of the maximal amount of inhibition was already reached on incubation of equimolar ratios of 1,4-TCBQ and subunit GST, while approximately 1 nmol (0.82-0.95) 1,4-[U- 14C]TCBQ per nmol subunit GST could be covalently bound. These results suggest that these GST isoenzymes possess only one cysteine in or near the active site of GST, which is completely responsible for the inhibition. In agreement, human isoenzyme B2B2 which possesses no cysteine, was not inhibited and no 1,4-TCBQ was bound to it. The rate of inhibition was studied at 0°: 1,4-TCBQ, trichloro-l,4-benzoquinone and GS-1,4-TCBQ all inhibit GST very fast. Especially for B1B1, the inhibition by the glutathione conjugate is significantly faster than inhibition by 1,4-TCBQ: the glutathione moiety seems to target the quinone to the enzyme. For the other isoenzymes only minor differences are observed between 1,4-TCBQ and its glutathione conjugate under the conditions used.

Independent segregation of glutathione S-transferase and fatty acid ethyl ester synthase from pancreas and other human tissues

Glutathione S-transferase (GST) isoenzymes of human pancreas were purified, characterized and evaluated for their possible role in the metabolism of ethanol. Human pancreas has at least two GST isoenzymes belonging to the Alpha class (pI 8.8 and 8.1), one belonging to the Mu class (pI 6.4) and one belonging to the Pi class (pI 4.9). During the purification of GSTs from pancreas as well as from heart, liver, lung, brain and muscle, the fatty acid ethyl ester synthase (FAEES) activity was monitored in order to evaluate the role of GSTs in metabolism of ethanol, as suggested in earlier studies. Both t.l.c. and h.p.l.c. were used to identify ethyl oleate in reaction mixtures to monitor FAEES activity. During the purification of GSTs with the use of affinity chromatography on GSH linked to epoxy-activated Sepharose 6B, FAEES and GST activities from each of these tissues segregated independently. Purified GST isoenzymes from these tissues did not exhibit any FAEES activity. Antibodies raised against Pi-class GST, as expected, immunoprecipitated most of the GST activity of brain and heart without precipitating FAEES activity. These results suggest that human GST isoenzymes belonging to the Alpha, Mu and Pi classes do not express FAEES activity. The independent segregation of GST and FAEES activities was further demonstrated by monitoring GST activity during the purification of FAEES from pancreas. It was found that purified FAEES had no GST activity towards 1-chloro-2,4-dinitrobenzene and a number of other electrophilic substrates. Results of these studies demonstrate that FAEES and GSTs are distinct proteins.

Genetic deficiency of human class mu glutathione S-transferase isoenzymes in relation to the urinary excretion of the mercapturic acids of Z- and E-1,3-dichloropropene

Mononuclear lymphocytes were isolated from the blood of 12 individuals, who had been exposed to the vapour of the soil fumigant 1,3-dichloropropene (DCP). Western blot experiments were performed on the crude lymphocyte homogenates, using a monoclonal antibody against human hepatic glutathione S-transferase (GST) isoenzyme mu, to determine the presence or absence of mu-class isoenzymes mu and/or psi. Nine of the individuals were found to be positive for mu and/or psi, the remaining three individuals being negative. In addition, all individuals showed a positive staining on immunoblot of a protein of somewhat lower molecular mass than the hepatic standard. This protein was bound by the S-hexylglutathione affinity column, and presumably constitutes a new mu-class isoenzyme, which is not subject to genetic polymorphism. Determination of the specific activities of individual human GST isoenzymes towards Z-(cis-) and E-(trans-)-DCP demonstrated that mu-class isoenzymes show a considerably higher specific activity with Z-DCP than alpha-class or pi-class isoenzymes. In addition, mu-class isoenzymes were found to be 2- to 3-fold more active with Z-DCP than with E-DCP. Their activity towards E-DCP was similar to the specific activity of alpha-class isoenzymes. Genetic polymorphism for mu-class isoenzymes could thus be a determinant in the extent of excretion of mercapturic acids from Z- and E-DCP. The urinary excretion of Z- and E-DCP mercapturic acids and the respiratory exposure to Z- and E-DCP were determined for nine and eight phenotyped individuals, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of rat and human glutathione S-transferase isoenzymes by ethacrynic acid and its glutathione conjugate

Ethacrynic acid, a potent inhibitor of glutathione S-transferases (GST), has been shown to enhance the cytotoxicity of chlorambucil in drug resistant cell lines, but a definite mechanism has not been established. Both covalent binding to GST and reversible inhibition of GST have been reported. In the present study no irreversible inhibition was observed: for all rat GST tested, inactivation was complete within 15 sec at 0°, and dialysis of GST after incubation with ethacrynic acid gave complete recovery of enzyme activity for all isoenzymes tested. Moreover, the inhibition was competitive towards 1-chloro-2,4-dinitrobenzene and non-competitive towards glutathione for rat isoenzyme 1-1. Strong inhibition of both human and rat GST of the α-, μ- and π-classes was obtained with ethacrynic acid, while conjugation of ethacrynic acid with glutathione did not abolish its inhibiting properties. For the α-, μ- and π-class i 50 values (μM) were 4.6–6.0, 0.3–1.9 and 3.3–4.8, respectively for ethacrynic acid, and 0.8–2.8, < 0.1–1.2 and 11.0, respectively for its glutathione conjugate. Of all isoenzymes tested the human isoenzyme μ is most sensitive to the action of both ethacrynic acid and its glutathione conjugate.

Inhibition of human glutathione S-transferases by bile acids

Glutathione S-transferase (GST) isoenzymes isolated from various human tissues are differentially inhibited by bile acids. Trihydroxy bile acid (lithocholate) was found to be more inhibitory to all the human GST isoenzymes tested in this study, as compared to the monohydroxy (cholate) and dihydroxy (chenodeoxycholate) bile acids. Among the three major classes of GST, μ class isoenzymes are generally inhibited to a greater extent than the α and π class isoenzymes. The results of this study also indicate that differential inhibition of GST by various bile acids may be used to distinguish closely related GST isoenzymes within the μ class of GST isoenzyme. Likewise, the π class or the anionic isoenzymes of human kidney, placenta, and erythrocytes can be distinguished using bile acid inhibition studies. These studies also provide further support for tissue-specific expression of GST isoenzymes in humans.

Differential inhibition of rat and human glutathione S-transferase isoenzymes by plant phenols

Glutathione S-transferase (GST) isoenzymes isolated from human tissues and rat liver are differentially inhibited by quercetin, alizarin, purpurogallin and ellagic acid. Rat liver GST isoenzymes are far more sensitive to these compounds as compared to the human GST isoenzymes. Among human GST, the anionic isoenzymes containing C type and A' type subunits are inhibited to a greater extent as compared to the cationic isoenzymes containing A and B type subunits. The anionic GST isoenzymes of human erythrocytes and placenta are differentially inhibited by these plant phenols indicating that the placental and erythrocyte isoenzymes may be distinct proteins.