Clinical and biochemical studies on the gluthathione S-transferases

Sherman, Morris

January 1982

The glutathione S-transferases (ligandins) are a ubiquitous system of xenobiotic metabolising enzymes. In the rat liver they comprise up to 10% of soluble hepatic protein. Studies in the rat suggested that ligandin was an accurate and sensitive marker of hepatocellular necrosis. and of renal tubular necrosis. The first part of this thesis examines the release of ligandin from liver and kidney in human liver and renal disease in an attempt to determine whether the measurement of ligandin is clinically useful. Ligandin was purified from human liver cytosol using a combination of anion exchange chromatography and gel filtration. The purified protein had similar physicochemical characteristics to ligandin purified by others. The protein was used to raise a monospecific antibody. Ligandin was iodinated by the Chloramine-T method. which yielded a labelled protein of high specific activity. A sensitive and specific radioimmunoassay for human ligandin was developed which had a low intra- and interassay variation. The assay was applied to the study of human liver disease. In acute hepatitis ligandin is released from the liver into serum early in the illness. High serum ligandin levels are seen in the first week of acute hepatitis. The rapid return to normal suggests that ligandin may provide an early indication of recovery. In chronic hepatitis ligandin levels correlated significantly with histological severity of disease. whereas SGOT showed no such correlation. Ligandin may be a better index of severity of disease and for treatment than SGOT. Ligandin was released from the kidney in severe renal ischaemia and in acute tubular necrosis, but was not a reliable predictor or indicator of acute tubular necrosis. Part two examines the distribution of GSH-T activity in organs and in hepatocellular carcinoma. Ligandin was shown to be immunologically similar in all tissues studied. Isoelectric focusing of cytosol separated the three groups of GSH-T activity. Considerable variety in the distribution and activity of GSH-T's was shown in different organs from a single donor, and in the same organs from different donors. Anionic transferase activity was shown to contribute a significant proportion of activity in organs other than the liver. and to be the major source of activity in ovary and lung. In hepatocellular carcinoma cationic GSH-T activity was present in amounts varying from near normal to absent. The anionic and neutral GSH-T's were present in amounts similar to that seen in normal liver. Immunohistochemical studies using a peroxidase-antiperoxidase method showed a rough correlation between tumour differentiation and the amount of ligandin in the tumour.

Glutathione transferases

The glutathione S-transferases : inhibition, activation, binding and kinetics

Thumser, Alfred Ernst Adolf

06 April 2018

No description available.

Glutathione transferases

Polymorphism in loci encoding detoxyfying enzymes : its role in cancer susceptibility and outcome

Bamber, Dianne Elizabeth

January 2001

No description available.

572

Glutathione transferases

Ligandin in the steroidogenic tissues of the rat : characterisation, distribution and development

Eidne, Karin Ann

January 1982

One of the main problems in the field of multifunctional proteins such as ligandin is the possibility that multiple forms and isoproteins may exist. Two forms of liver ligandin [ GSH (reduced glutathione) S-transferase B] have been described, a heterodimeric form consisting of equal amounts of Ya (22000 daltons) and Yc (25000 daltons) subunits, and a homodimeric form containing only Ya. Because rat testis ligandin, prepared by the standard technique of anion-exchange and molecular exclusion chromatography, contains more Yc subunit than Ya, it has been claimed that testis and liver ligandin are different entities (Bhargava, Ohmi, Listowsky and Arias (1980) J. Biol. Chem. 255, 724-727). This thesis investigated the nature and character of ligandin in the steroid-producing tissues of the rat. A comparative study was undertaken to establish whether testis ligandin differed from liver ligandin. Different methods of purification were used to investigate testis ligandin and its relationship to other GSH S-transferases in steroidogenic tissues. Testis ligandin purified by immunoaffinity chromatography using anti-liver YaYa ligandin antiserum yielded a product identical with liver preparations (Yc=Ya). This suggests that the differences previously described may be due to contamination of testis ligandin by a closely related species. Testis ligandin prepared by the standard technique was similar to that previously reported, containing more Yc than Ya. Cross-linking studies of standard testis ligandin preparations with dimethylsuberimidate showed more than one band in the 50000 dalton region, further strengthening the view that these testis ligandin preparations may be contaminated. Since this contaminant was likely to be another GSH S-transferase, sodium dodecyl sulphate/ polyacrylamide-gel-electrophoretic analysis was performed on testis GSH S-transferases separated by CM-cellulose chromatography. GSH S-transferase AA which was present in large amounts, was shown to migrate in the same region as Yc subunit. CM-cellulose chromatography of a 'pure' standard testis ligandin preparation revealed significant amounts of GSH S-transferase AA migrating as Yc subunit, in addition to ligandin consisting of equal amounts of Ya and Yc subunits, indicating that testis ligandin is identical with liver ligandin and that previously described differences are due to a contaminant identified as GSH S-transferase AA. Studies on ligandin in other steroid-synthesising tissues showed that ovary and adrenal ligandin prepared by standard techniques also contained more Yc than Ya. Separation of ovary GSH S-transferases on CM-cellulose showed that GSH S-transferase B, the peak reacting with anti-liver YaYa ligandin antisera contained equal amounts of Ya and Y c subunits, suggesting a situation similar to that in the testis exists. Glutathione peroxidase II activity of testis and ovary GSH S-transferases was investigated. Fractions corresponding to GSH S-transferase AA, A and B exhibited activity with cumene hydroperoxide. The considerable glutathione peroxidase activity of GSH S-transferases in testis and ovary suggest a protective function for the cells of gonadal tissue against oxidative damage to essential intracellular components. Further attempts to clarify the function of ligandin in the steroid-synthesising tissues were made. The pattern of gonadal ligandin development during early life, puberty and pregnancy determined by radioimmunoassay was found to parallel serum steroid hormone concentrations. This correlation was not observed in liver or kidney. Ligandin was localised to specific cells of the steroid synthesising tissues using immunocytochemical techniques. These findings suggest that there may be a functional link between steroidogenic cells, or products of their activity and certain GSH S-transferases. Phenobarbital pre-treatment did not have any effect on developing testis, ovary or adrenal ligand in concentrations. Immunocytochemical localisation of ligandin in rat steroid-producing tissues using a peroxidase anti-peroxidase (PAP) technique with anti-liver YaYa ligandin antiserum as the first antibody, showed staining in the testis to be limited to the interstitial (Leydig) cells. Stromal cells of the ovary and the fascicular, glomerular and reticular zones of the adrenal cortex also contained immunoreactive material. PAP staining with anti-testis ligandin antisera (testis ligandin prepared using the standard technique) showed far greater intensity of staining in these tissues, presumably due to reaction with both ligand in and GSH S-transferase AA. This study has clarified the structural aspects of testis ligandin and demonstrated identity with liver ligandin. Ontogeny of ligandin in the steroidogenic tissues and localisation to specific regions in these tissues suggests a functional link between ligandin, GSH S-transferases, GSH peroxidases and activity of steroidogenic tissue.

Peroxidases

Glutathione transferases

Human glutathione S-transferases : characterization, tissue distribution and kinetic studies

Corrigall, Anne Vint

January 1988

In this study the purification of human basic and near-neutral liver, and human basic and acidic lung glutathione S-transferases (GSH S-T) was undertaken. Purification of the basic and near-neutral GSH S-T was achieved using a combination of affinity chromatography, chromatofocusing and immunoaffinity chromatography. Affinity and ion exchange chromatography were employed in the purification of the basic and acidic lung forms. The purified proteins had similar physicochemical characteristics to the GSH S-T purified by others. The binding of 1-chloro-2,4-dinitrobenzene (CDNB) to the 3 classes of human GSH S-T, viz. basic, near-neutral and acidic and the effects of such binding, if any, were examined. Human acidic lung GSH S-T is irreversibly inactivated by CDNB in the absence of the co-substrate glutathione (GSH). The time-dependent inactivation is pseudo-first order and demonstrates saturation kinetics, suggesting that inactivation occurs from an EI complex. GSH protects the enzyme against CDNB inactivation. In contrast, the basic and near-neutral GSH S-T are not significantly inactivated by CDNB. Incubation with [¹⁴C]-CDNB indicated covalent binding to all 3 classes of GSH S-T. When the basic and acidic GSH S-T were incubated with [¹⁴C]-CDNB and GSH, cleaved with cyanogen bromide, and chromatographed by HPLC, a single peptide fraction was found to be labelled in both classes. Incubation in the absence of GSH yielded 1 and 2 additional labelled peptide fractions for the basic and acidic transferases, respectively. These results suggest that while CDNB arylates all 3 classes of human GSH S-T, only the acidic GSH S-T possesses a specific GSH-sensitive CDNB binding site, which when occupied leads to time-dependent inactivation of the enzyme. The tissue distribution and localization of the 3 classes of human GSH S-T in normal and tumour tissue was examined. Antibodies to representatives of the 3 classes were raised in rabbits, and radial immunodiffusion employed to quantitate their concentrations in the cytosol of 18 organs from 9 individuals. The data provide the first direct, quantitative evidence for the inter-individual and inter-organ variation suggested by earlier workers. The absence of the near-neutral GSH S-T in 5 of the 9 individuals studied confirms an earlier suggestion of a "null" allele for this transferase. Basic and acidic GSH S-T (apart from in a single liver), were always present. Near-neutral GSH S-T, when present, were found in all tissues examined. The marked inter-organ and inter-individual variation observed in this study may explain individual and organ susceptibility to drugs, toxins and carcinogens. The immunohistochemical localization of the 3 classes of GSH S-T reveals important differences in their localization, and may provide insight into their functions in various organs and tissues.

Glutathione transferase

Glutathione transferases

The glutathione S-transferases : kinetics, binding and inhibition

Goold, Richard David

January 1989

The glutathione S-transferases are a group of enzymes which catalyse the conjugation of reduced glutathione with a variety of electrophilic molecules, and they are therefore thought to play a major role in drug biotransformation and the detoxification of xenobiotics. The cytosolic GSH S-transferase isoenzymes of rat, man and mouse have been assigned to three groups, Alpha, Mu and Pi, based on N-terrninal amino acid sequences, substrate specificities, immunological cross-reactivity and sensitivities to inhibitors. The kinetic mechanism of the GSH S-transferases is controversial, due to the observation of non-Michaelian (non-hyperbolic) substrate-rate saturation curves. The most detailed investigations of the steady-state kinetics of glutathione S-transferase have been performed with isoenzyme 3-3 (class Mu) and the substrate 1,2-dichloro-4-nitrobenzene (DCNB). Explanations for the apparently anomalous non-hyperbolic kinetics have included subunit cooperativity, steady-state mechanisms of differing degrees of complexity and the superimposition of either product inhibition or enzyme memory on these mechanisms. This study has confirmed the biphasic kinetics for isoenzyme 3-3 with DCNB and shown non-hyperbolic kinetics for this isoenzyme with 1-chloro-2,4-dinitrobenzene (CDNB) and for isoenzyme 3-4 with DCNB and CDNB. It is proposed that the basic steady-state random sequential Bi Bi mechanism is the simplest mechanism sufficient to explain the non-hyperbolic kinetics of GSH S-transferases 3-3 and 3-4 under initial rate conditions. Neither more complex steady-state mechanisms nor the superimposition of product inhibition or enzyme memory on the simplest steady-state mechanism are necessary.

Medical Biochemistry

Glutathione transferase

Glutathione transferases

Glutathione transferases - Analysis

Target-guided synthesis approach to the discovery of novel bivalent inhibitors of glutathione transferases

Clipson, Alexandra Jayne

January 2012

Target-guided synthesis is an approach to drug discovery that uses the biological target as a template to direct synthesis of its own best inhibitors from small molecule fragments. The process bridges the gap between chemical synthesis of drug candidates and their biological binding assay, merging the two operations into a single process whereby the active site or a binding pocket within the structure of the biological target directly controls the assembly of the best inhibitor in situ. Two different approaches to target-guided synthesis, the thermodynamic approach, making use of reversible reactions, and the kinetic approach, which uses an irreversible reaction, have been employed to discover novel, isoform selective inhibitors of the glutathione transferase (GST) enzyme family – possible drug targets in cancer and parasitic disease treatments. The thermodynamic approach described in this thesis uses the aniline-catalysed reversible acyl hydrazone formation reaction to create a dynamic covalent library of bivalent ligands designed to bind the dimeric structure of GST. In the presence of GST one of the bivalent ligands was selectively amplified at the expense of the other library members. This ligand was shown, via biological assays, to be a specific inhibitor for one isoform of GST, the mu isoform mGSTM1-1. A kinetic approach has also been investigated as a way to identify novel bivalent GST inhibitors utilising the Huisgen 1, 3 dipolar cycloaddition reaction. An azide and alkyne fragment library was designed to bind across the dimeric GST structure. The inhibitor structures are therefore bivalent, containing two anchoring fragments known to bind to the GST active site, linked by a triazolopeptide spacer. The triazole provides the click chemistry disconnection, enabling rapid in situ screening of candidate alkyne and azide fragments for inhibitor discovery. Whilst the in situ reaction with GST yielded inconclusive results, a number of the triazole products were found to have low nanomolar inhibitory activity towards GST.

547

Studies on Human and Drosophila melanogaster Glutathione Transferases of Biomedical and Biotechnological Interest

Mazari, Aslam M.A.

January 2016

Glutathione transferases (GSTs, EC.2.5.1.18) are multifunctional enzymes that are universally distributed in all cellular life forms. They play important roles in metabolism and detoxication of endogenously produced toxic compounds and xenobiotics. GSTs have gained considerable interest over the years for biomedical and biotechnological applications due to their involvement in the conjugation of glutathione (GSH) to a vast array of chemical species. Additionally, the emergence of non-detoxifying functions of GSTs has further increased their biological significance. The present work encompasses four scientific studies aimed at investigating human as well as fruit fly Drosophila melanogaster GSTs. Paper I presents the immobilization of GSTs on nanoporous alumina membranes. Kinetic analyses with 1-chloro-2,4-dinitrobenzene followed by specificity screening with alternative substrates showed a good correlation between the data obtained from immobilized enzymes and the enzymes in solution. Furthermore, immobilization showed no adverse effects on the stability of the enzymes. Paper II presents inhibition studies of human hematopoietic prostaglandin D2 synthase (HPGDS), a promising therapeutic target for anti-allergic and anti-inflammatory drugs. Our screening results with an FDA-approved drug library revealed a number of effective inhibitors of HPGDS with IC50 values in the low micromolar range. Paper III concerns the toxicity of organic isothiocyanates (ITCs) that showed high catalytic activities with GSTE7 in vitro. The in vivo results showed that phenethyl isothiocyanate (PEITC) and allyl isothiocyanate in millimolar dietary concentrations conferred toxicity to the adult fruit flies leading to death or shortened life-span. The transgenic female flies overexpressing GSTE7 showed increased tolerance against PEITC toxicity compared to the wild-type. However, the effect was opposite in male flies overexpressing GSTE7 after one week exposure. Notably, the transgene enhanced the oviposition activity of flies with and without ITCs exposure. Paper IV highlights Drosophila GSTs as efficient catalysts of the environmental pollutant and explosive 2,4,6-trinitrotoluene and the related 2,4-dinitrotoluene degradation. This result suggests the potential of GST transgenes in plants for biotransformation and phytoremediation of these persistent environmental pollutants.

glutathione transferases

detoxication

hpgds inhibition

immobilization

isothiocyanates

drosophila GSTs

environmental pollutants

A mixed-charge cluster facilities glutathione transferase dimerisation

Walters, John Clive

14 November 2006

Student Number : 0213014A - MSc dissertation - School of Molecular and Cell Biology - Faculty of Science / Cytosolic glutathione transferases (GSTs) are obligate stable homo- and heterodimers comprising two GST subunits. Interactions across the subunit interface play an important role in stabilising the subunit tertiary structure and maintain the dimeric structure required for activity. The crystal structure of a rat Mu class GST consisting of two type one subunits (rGST M1-1) reveals a lock-and-key motif and a mixedcharge cluster at the subunit interface. Previous investigations revealed the lock-andkey motif was not essential for dimerisation. It was therefore postulated that the mixed-charge cluster at the dimer interface is primarily responsible for subunit association. Statistical analyses of individual rGST M1-1 chains did not predict the presence of any charge clusters. This suggests that the mixed-charge cluster forms only upon dimerisation and reinforces the probability that quaternary structure stabilisation is a major role of the mixed-charge cluster. Arginine 81 (Arg-81), a structurally conserved residue in the GST family involved in the mixed-charge cluster, was mutated to alanine. Phenylalanine 56 (Phe-56), the ‘key’ residue in the lock-and-key motif, was mutated to serine. These changes were engineered to disrupt the mixed-charge cluster and the lock-and-key motif situated at the dimer interface of rGST M1-1. Sizing by gel filtration chromatography of the mutant GST identified that these engineered amino acids resulted in a stable monomeric protein (F56S/R81A rGST M1). The F56S/R81A rGST M1 displayed almost no catalytic activity, suggesting perturbations of the active site or substrate binding sites. Structural investigations of the monomer by far- and near-UV circular dichroism revealed a similar secondary structural content to the wild-type. However, the tryptophan fluorescence properties suggested the tryptophans were situated in more hydrophilic environments than in the wild-type. ANS binding studies indicated a large increase in the accessible hydrophobic surface area of the monomer. Ureainduced equilibrium unfolding of F56S/R81A rGST M1 follows a cooperative twostate unfolding model. The unfolding data indicates decreased conformational stability and a large increase in the solvent exposed surface area of the monomer. In conclusion, the mixed-charge cluster at the dimer interface of rGST M1-1 is essential for monomeric association, which subsequently contributes to catalytic activity of the dimer and the stabilities of individual rGST M1-1 subunits.

oligomerisation

oligomeric assemblies

Cytosolic glutathione transferases

GST

charge clusters

filtration chromatography

Role of Multiple Glutathione Transferases in Bioactivation of Thiopurine Prodrugs : Studies of Human Soluble Glutathione Transferases from Alpha, Kappa, Mu, Omega, Pi, Theta, and Zeta Classes

Eklund, Birgitta I.

January 2006

<p>A screening method was developed for identification of catalytically active enzymes in combinatorial cDNA libraries of mutated glutathione transferase (GST) derivatives expressed in <i>E. coli</i>. The method is based on spraying monochlorobimane (MCB) directly over bacterial colonies growing on agar. The substrate MCB become fluorescent under UV light, when the bacterial colony contains active GSTs catalyzing the conjugation with endogenous glutathione. Eleven out of twelve GSTs investigated where active with MCB. This method can be used to screen libraries generated from most cytosolic GSTs in the search for proteins with altered functions and structures. Azathioprine (Aza), a thiopurine that has been used clinically for 40 years was investigated with 14 GSTs. Three enzymes showed prominent catalytic activities with Aza and all of them are highly expressed in the liver. We estimated the contribution of the three enzymes GSTs A1-1, A2-2 and M1-1 bioactivation of Aza in the liver and concluded that it was about 2 orders of magnitude more effective than the uncatalyzed reaction. GST bioactivation of Aza could clarify aspects of idiosyncratic reactions observed in some individuals. Two other thiopurine prodrugs, cis-acetylvinylthiopurine (cAVTP) and trans-acetylvinylthioguanine (tAVTG), were investigated with the same 14 GSTs. The results displayed diverse catalytic activities. A mechanism of consecutive reactions was proposed. The studies contribute to knowledge under what conditions the drug should optimally be administered. A study of the same prodrugs with several mutants from the Mu class characterized by a point mutation of a hypervarible residue. We conclude that the effects of the mutations were qualitatively parallel for cAVTP and tAVTG, but they vary significantly in magnitude; steric hindrance may interfere with transition-state stabilization. From the evolutionary perspective the data show that a point mutation can alternatively enhance or attenuate the activity with a particular substrate and illustrate the functional plasticity of GSTs.</p>

Biochemistry

Glutathione Transferases

Thiopurines

Prodrug

Bioactivation

Screening Method

Chemotherapy

Functional plasticity

Modulated activity

Biokemi