Glutathione-related enzymes,glutathione and multidrug resistance

This review examines the hypothesis that glutathione and its associated enzymes contribute to the overall drug-resistance seen in multidrug resistant cell lines. Reports of 34 cell lines independently selected for resistance to MDR drugs are compared for evidence of consistent changes in activity of glutathione-related enzymes as well as for changes in glutathione content. The role of glutathione S-transferases in MDR is further analyzed by comparing changes in sensitivity to MDR drugs in cell lines selected for resistance to non-MDR drugs that have resulting increases in glutathione S-transferase activity. In addition, results of studies in which genes for glutathione S-transferase isozymes were transfected into drug-sensitive cells are reviewed. The role of the glutathione redox cycle is examined by comparing changes in elements of this cycle in MDR cell lines as well as by analyzing reports of the effects of glutathione depletion on MDR drug sensitivity. Overall, there is no consistent or compelling evidence that glutathione and its associated enzymes augment resistance in multidrug resistant cell lines.     

Inevitable glutathione,then and now

Glutathione a predominant tripeptide thiol compound of many prokaryotes and eukaryotes, is synthesized from its precursor amino acids eg. gamma-glutamate, cysteine and glycine. It is mainly involved in detoxication mechanisms through conjugation reactions. Other functions include thiol transfer, destruction of free radicals and metabolism of various exogenous and endogenous compounds. It becomes mandatory for a cell to manage high concentration of intracellular GSH to protect itself from chemical/dug abuse. Glutathione dependent enzymes viz: glutathione-S-transferases, glutathione peroxidase, glutathione reductase and gamma-glutamate transpeptidase facilitate protective manifestations. Liver serves as a glutathione-generating factor which supplies the kidney and intestine with other constituents of glutathione resynthesis. The principal mechanism of hepatocyte glutathione turnover appears to be cellular efflux. Kidney too plays an important role in organismic GSH homeostasis. Role of GSH in organs like lung, intestine and brain has recently been described. GSH involvement in programmed cell death has also been indicated. Immense interest makes the then "thee glutathione" as "inevitable glutathione". This article describes the role of this vital molecule in cell physiology and detoxication mechanisms in particular.     

Acidic glutathione S-transferases of rat testis.

In most organs of the rat the predominant forms of glutathione S-transferase have alkaline (greater than 7.0) pI values. In contrast, in the cytosol from rat testes almost 50% of the transferase activity is due to isoenzymes with acidic (less than 7.0) pI values. We have purified three acidic forms of glutathione S-transferase from rat testis cytosol. One form accounted for more than 90% of the enzymic activity in the acidic fraction. This major form was a homodimer of a new subunit, termed Yt. This subunit had an electrophoretic mobility that was different from the subunits that form the alkaline transferases. In addition, functional and immunological studies were consistent with the unique nature of the Yt subunit. The two minor acidic enzymes of rat testis appeared to be heterodimers of the Yt subunit and a subunit with an electrophoretic mobility identical with that of the Yb subunit present in some alkaline enzymes.     

Redox metabolism of glutathione in the red blood cell.

A theoretical study of the biochemical and clinical aspects of the reduction-oxidation metabolism of glutathione in the mature red blood cell is presented. A summarizing survey of the literature data has led to the formulation of a mathematical model which comprises the kinetic properties of the enzymes partaking in the hexose monophosphate pathway (HMP) and the oxidation of NADPH and GSH. The model takes the form of a system of differential equations describing the motion of metabolites in one cell. The interactions between metabolites ane enzymes, in particular between glutathione and the SH-dependent enzymes of glucose phosphorylation and HMP have been included into the model...     

Enzymatic synthesis of novel glutathione analogs

A strain of Escherichia coli enriched in its content of gamma-glutamylcysteine synthetase and glutathione synthetase by recombinant DNA techniques has been immobilized in a carrageenan matrix and used for the synthesis of various types of isotopically labeled glutathione (L-gamma-glutamyl-L-cysteinyl-glycine) (K. Murata, W. A. Abbott, R. J. Bridges, and A. Meister (1985) Anal. Biochem. 150, 235-237). In the present work, this E. coli matrix was used as the basis of a method for the synthesis of glutathione analogs. Thus, amino acid analogs were used in place of the corresponding amino acid constituents of glutathione (e.g., 4-fluoroglutamate was substituted for glutamate) in the reaction mixtures. Using this method we have synthesized several analogs of glutathione including L-gamma-glutamyl-(beta-chloro)-L-alanyl-glycine, (R,S)-4-fluoro-DL-gamma-glutamyl-L-cysteinyl-glycine, D-gamma-glutamyl-L-cysteinyl-glycine, and L-gamma-glutamyl-L-homocysteinyl-glycine. This method may also be used for the synthesis of a number of L- and D-gamma-glutamyl amino acids. The analogs are purified by gel-filtration and ion-exchange chromatography. The analogs are used to examine the substrate specificity and mechanisms of action of glutathione-utilizing enzymes and for studies on glutathione metabolism and function. Fluorine-containing analogs may be used for NMR studies. The enzymatically prepared compounds may also be used as intermediates in the chemical synthesis of other analogs of glutathione and glutathione disulfide.     

Redox regulation of homocysteine-dependent glutathione synthesis

In certain tissues, glutathione biosynthesis is connected to methionine metabolism via the trans-sulfuration pathway. The latter condenses homocysteine and serine to cystathionine in a reaction catalyzed by cystathionine beta-synthase followed by cleavage of cystathionine to cysteine and alpha-ketoglutarate by gamma-cystathionase. Cysteine is the limiting amino acid in glutathione biosynthesis, and studies in our laboratory have shown that approximately 50% of the cysteine in glutathione is derived from homocysteine in human liver cells. In this study, we have examined the effect of pro- and antioxidants on the flux of homocysteine through the trans-sulfuration pathway in the human hepatoma cell line, HepG2. Our studies reveal that pyrrolidine dithiocarbamate and butylated hydroxyanisole enhance the flux of homocysteine through the trans-sulfuration pathway as has been observed previously with the pro-oxidants, H(2)O(2) and tertiary butyl hydroperoxide. In contrast, antioxidants such as catalase, superoxide dismutase and a water-soluble derivative of vitamin E elicit the opposite effect and result in diminished flux of homocysteine through the trans-sulfuration pathway. These studies provide the first evidence for the reciprocal sensitivity of the trans-sulfuration pathway to pro- and antioxidants, and demonstrate that the upstream half of the glutathione biosynthetic pathway (i.e. leading to cysteine biosynthesis) is redox sensitive as is the regulation of the well-studied enzymes in the downstream half (leading from cysteine to glutathione), namely, gamma-glutamyl-cysteine ligase and glutathione synthetase.     

Susceptibility of cord blood antioxidant enzymes glutathione reductase,glutathione peroxidase and glutathione S-transferase to different antibiotics: in vitro approach

Cord blood has numerous facilities for life and used in many different areas. Cord blood contains many different catalytic proteins including antioxidant enzymes. Here we purified human cord blood glutathione reductase (hcbGR), glutathione S-transferase (hcbGST) and human cord blood glutathione peroxidase (hcbGPx) from human cord blood erythrocytes and analyzed the inhibition effects of the antibiotics incorporating cefuroxime, ceftriaxone, ceftizoxime and cefoperazone, on these enzymes. K_I values for the drugs ranged from 10.42 to 28.72 µM for hcbGR, 32.7 to 244.8 µM for hcbGPx, and 32.39 to 267.3 µM for hcbGST. Cefuroxime caused the highest inhibition on all enzymes with K_I values of 10.42, 32.39, 32.7 µM for hcbGR, hcbGST, and hcbGPx, respectively. All drugs displayed non-competitive inhibition regardless of their structures. Since these drugs are often used during pregnancy, identification of possible undesired impacts on various parameters has a great importance for pharmacological and medical applications.     

Site-directed mutagenesis of glutathione S-transferase YaYa. Important roles of tyrosine 9 and aspartic acid 101 in catalysis.

The roles of tyrosine 9 and aspartic acid 101 in the catalytic mechanism of rat glutathione S-transferase YaYa were studied by site-directed mutagenesis. Replacement of tyrosine 9 with phenylalanine (Y9F), threonine (Y9T), histidine (Y9H), or valine (Y9V) resulted in mutant enzymes with less than 5% catalytic activity of the wild type enzymes. Kinetic studies with purified Y9F and Y9T mutants demonstrated poor catalytic efficiencies which were largely due to a drastic decrease in kcat. The estimated pK alpha values of the sulfhydryl group of glutathione bound to Y9F and Y9T mutant enzymes were 8.5 to 8.7, similar to the chemical reaction, in contrast to the estimated pK alpha value of 6.7 to 6.8 for the glutathione enzyme complex of wild type glutathione S-transferase. These results indicate that tyrosine 9 is directly responsible for the lowering of the pKa of the sulfhydryl group of glutathione, presumably due to the stabilization of the thiolate anion through hydrogen bonding with the hydroxyl group of tyrosine. To examine the role of aspartic acid in the binding of glutathione to YaYa, 4 conserved aspartic acid residues at positions 61, 93, 101, and 157 were changed to glutamic acid and asparagine. All mutant enzymes retained either full or partial activity except D157N, which was virtually inactive. Kinetic studies with four mutant enzymes (D93E, D93N, D101E, and D101N) indicate that only D101N exhibited a 5-fold increase in Km toward glutathione. Also, the binding of this mutant to the affinity column was greatly reduced. These results demonstrate that aspartic acid 101 plays an important role in glutathione interaction to YaYa. The role of aspartic acid 157 in catalysis remains to be determined.     

The effect of phenobarbital, ionol and cAMP on the activity of glutathione metabolism enzymes in rodents

The phenobarbital and ionol administration to rats and mice increases considerably the glutathione transferase, glutathione reductase and gamma-glutamyl transferase activities in the liver. The induction of these enzymes has been observed in a number of experiments in the heart and kidney but it was less pronounced. A correlation was established between the induction of glutathione transferase, glutathione reductase and gamma-glutamyl transferase, their changes in mice and rats, phenobarbital and ionol effects. The stimulatory effect of cAMP on glutathione transferase in the liver (and in a number of experiments in the heart) increased against a background of the both agents. The cAMP-dependent activation of glutathione peroxidase was retained in the heart but in some series experiments it disappeared in the liver and kidney. Mechanisms of the long-term (induction) and short-term (cAMP) elevation of the glutathione transferase and glutathione peroxidase activities functioned independently and often in concord. It is suggested that induction of glutathione metabolism enzymes may play an important role in biological effects of ionol.     

S-(4-Nitrophenacyl)glutathione is a specific substrate for glutathione transferase omega 1-1

Glutathione transferase omega 1-1 (GSTO1-1) catalyzes the biotransformation of arsenic and is implicated as a factor influencing the age-at-onset of Alzheimer’s disease and the posttranslational activation of interleukin 1β (IL-1β). Investigation of the biological role of GSTO1-1 variants has been hampered by the lack of a specific assay for GSTO1-1 activity in tissue samples that contain other GSTs and other enzymes with similar catalytic specificities. Previous studies (P. G. Board and M. W. Anders, Chem. Res. Toxicol. 20 (2007) 149-154) have shown that GSTO1-1 catalyzes the reduction of S-(phenacyl)glutathiones to acetophenones. A new substrate, S-(4-nitrophenacyl)glutathione (4NPG), has been prepared and found to have a high turnover with GSTO1-1 but negligible activity with GSTO2-2 and other members of the glutathione transferase superfamily. A spectrophotometric assay with 4NPG as a substrate has been used to determine GSTO1-1 activity in several human breast cancer cell lines and in mouse liver and brain tissues.     

Structure-activity relationships of 4-hydroxyalkenals in the conjugation catalysed by mammalian glutathione transferases.

The substrate specificities of 15 cytosolic glutathione transferases from rat, mouse and man have been explored by use of a homologous series of 4-hydroxyalkenals, extending from 4-hydroxypentenal to 4-hydroxypentadecenal. Rat glutathione transferase 8-8 is exceptionally active with the whole range of 4-hydroxyalkenals, from C5 to C15. Rat transferase 1-1, although more than 10-fold less efficient than transferase 8-8, is the second most active transferase with the longest chain length substrates. Other enzyme forms showing high activities with these substrates are rat transferase 4-4 and human transferase mu. The specificity constants, kcat./Km, for the various enzymes have been determined with the 4-hydroxyalkenals. From these constants the incremental Gibbs free energy of binding to the enzyme has been calculated for the homologous substrates. The enzymes responded differently to changes in the length of the hydrocarbon side chain and could be divided into three groups. All glutathione transferases displayed increased binding energy in response to increased hydrophobicity of the substrate. For some of the enzymes, steric limitations of the active site appear to counteract the increase in binding strength afforded by increased chain length of the substrate. Comparison of the activities with 4-hydroxyalkenals and other activated alkenes provides information about the active-site properties of certain glutathione transferases. The results show that the ensemble of glutathione transferases in a given species may serve an important physiological role in the conjugation of the whole range of 4-hydroxyalkenals. In view of its high catalytic efficiency with all the homologues, rat glutathione transferase 8-8 appears to have evolved specifically to serve in the detoxication of these reactive compounds of oxidative metabolism.     

Glutathione and glutathione metabolizing enzymes in yeasts

Total glutathione content, glutathione peroxidase, glutathione transferase and glutathione reductase activities have been measured in 12 species of yeasts. All the strains tested contained glutathione, though in different amounts, as well as the above mentioned enzymes. To discriminate between the selenium-dependent and the selenium-independent form, glutathione peroxidase activity has been measured with both H₂O₂ and cumene hydroperoxide. Rhodotorula glutinis appeared to be the only strain in which the selenium-dependent form was not found, but this yeast exhibited the highest level of selenium-independent glutathione peroxidase activity as compared to the other strains.     

CuZn superoxide dismutase, Mn superoxide dismutase, catalase and glutathione peroxidase in glutathione-deficient human fibroblasts

The effect of genetically determined glutathione deficiency on the fibroblast content of CuZn superoxide dismutase, Mn superoxide dismutase, catalase and glutathione peroxidase was investigated. No significant differences between glutathione-deficient and -proficient human fibroblasts were revealed. There was a large variation in the content of the investigated enzymes in fibroblasts grown and analysed on different occasions. Whereas the contents of CuZn superoxide dismutase, catalase and glutathione peroxidase did not deviate much from what has been found in other human cell-lines and tissues, the fibroblasts were found to contain exceptional amounts of Mn superoxide dismutase.     

Prospects for enhancement of the soluble antioxidants,ascorbate and glutathione

Ascorbic acid (vitamin C) and the tripeptide thiol, glutathione gamma-glutamyl cysteinyl glycine (glutathione) are the major low molecular weight soluble antioxidants in plant cells. The pathway of glutathione biosynthesis is similar in animals and plants while that of ascorbate biosynthesis differs considerably between the two kingdoms. The potential for obtaining substantial constitutive changes in the tissue contents of these antioxidants by manipulation of the biosynthetic enzymes has been demonstrated. Moreover, the concentrations of ascorbate and glutathione are greatly modified in response to a variety of environmental triggers, particularly those that cause increased oxidative stress. It is essential that the signals and associated signal transduction pathways that trigger enhanced antioxidant accumulation are elucidated as these offer an important alternative means of achieving greater nutritional value in edible plant organs.     

Cadmium resistance in A549 cells correlates with elevated glutathione content but not antioxidant enzymatic activities

Glutathione has been implicated to function in cytoprotection against cadmium toxicity. The mechanism by which glutathione plays this role has not been well understood. Because glutathione is an important antioxidant and several studies have shown that cadmium induces oxidative stress, this study was undertaken to determine whether development of cadmium resistance is linked to enhanced antioxidant activities. A cadmium-resistant subpopulation of human lung carcinoma A549 cells, which was developed by repeatedly exposing the cells to step-wise increased cadmium concentrations, was compared to a cadmium-sensitive one. The acquired cadmium resistance resulted from neither decreased cadmium uptake nor enhanced cellular metallothionein synthesis. Glutathione content, however, was markedly elevated in the cadmium-resistant cells. In contrast, the activities of the glutathione redox cycle related enzymes, glutathione peroxidase and reductase, were unchanged. Two other antioxidant enzymes, superoxide dismutase and catalase, were also not altered. The results suggest that the development of cadmium resistance in A549 cells unlikely results from enhanced antioxidant enzyme activities, although it is associated with elevated cellular glutathione levels. In addition, measurement of the mRNA and DNA levels for γ-glutamyleysteine synthetase, the rate-limiting enzyme for glutathione biosynthesis, revealed that enhanced expression of the enzyme but not gene amplification is likely responsible for the elevation of cellular glutathione levels.     

Effect of cigarette smoke extract on the polymorphonuclear leukocytes chemiluminescence: influence of a filter containing glutathione.

Cigarette smoking is known to be a risk factor for several chronic and neoplastic diseases. Many compounds formed by cigarette burning, ranging from particulate materials to water solutes and gaseous extracts, are considered to be noxious agents, and many biochemical and molecular mechanisms have been proposed for the toxic effects of cigarette smoke. The oral cavity and the upper respiratory tract represent the first contact areas for smoke compounds; even a single cigarette can produce marked effects on some components of the oral cavity, either chemical compounds, such as glutathione and enzymes, or cellular elements, such as polymorphonuclear leukocytes. Several studies suggest a protective role of glutathione against the noxious effects of tobacco smoke; the sulphydril groups of glutathione, in fact, could react with some smoke products, such as unsaturated aldehydes, leading to the formation of harmless intermediate compounds and simultaneously preventing the inactivation of metabolically essential molecules, such as some enzymes. In this paper we analyse the effect of a filter containing glutathione on the respiratory burst of polymorphonuclear leukocytes exposed to aqueous extract of cigarette smoke, measuring their chemiluminescence activity. The results of this paper indicate that the GSH-containing filter has a likely protective effect against the inhibition of cigarette smoke extract on polymorphonuclear leukocyte activity.     

Irreversible inhibition of hepatic glutathione S-transferase by ciprofibrate, a peroxisome proliferator

Ciprofibrate (2-[4-(2,2-dichlorocyclopropyl) phenoxy]2-methyl propionic acid) which is a hypolipidemic agent and has been shown to cause peroxisome proliferation, non-competitively inhibits glutathione S-transferase activity of rat liver, both in vivo and in vitro. Among all the glutathione S-transferases of rat liver, ligandin is maximally inhibited by ciprofibrate. Studies with the purified glutathione S-transferases of rat liver indicate that the affinities of different subunits of liver enzymes for ciprofibrate are in the order Ya greater than Yb, Yb' greater than Yc.     

The nuclear glutathione and its functions

During recent years the nuclear localization of glutathione has been confirmed and this fraction has been quantitatively determined. The nuclear GSH and the enzymes of its metabolism realize independent and important functions. They considerably differ from functions of hyaloplasmic and mitochondrial GSH. Glutathione interacts with regulatory pathways, involved into signal transmission into the nucleus.     

Identification of a novel glutathione transferase in human skin homologous with class alpha glutathione transferase 2-2 in the rat.

Six forms of glutathione transferase with pI values of 4.6, 5.9, 6.8, 7.1, 8.5 and 9.9 have been isolated from the cytosol fraction of normal skin from three human subjects. The three most abundant enzymes were an acidic Class Pi transferase (pI 4.6; apparent subunit Mr 23,000), a basic Class Alpha transferase (pI 8.5; apparent subunit Mr 24,000) and an even more basic glutathione transferase of Class Alpha (pI 9.9; apparent subunit Mr 26,500). The last enzyme, which was previously unknown, accounts for 10-20% of the glutathione transferase in human skin. The novel transferase showed greater similarities with rat glutathione transferase 2-2, another Class Alpha enzyme, than with any other known transferase irrespective of species. The most striking similarities included reactions with antibodies, amino acid compositions and identical N-terminal amino acid sequences (16 residues). The close relationship between the human most basic and the rat glutathione transferase 2-2 supports the classification of the transferases previously proposed and indicates that the similarities between enzymes isolated from different species are more extensive than had been assumed previously.     

Studies on glutathione S-alkyltransferase of the rat

1. A rat-liver enzyme catalysing the S-alkylation of glutathione by iodomethane and various other alkyl compounds has been identified and partially purified; its stability, specificity and response to inhibitors and activators and to changes in reaction pH have been studied. 2. The enzyme is distinct from glutathione S-aryltransferase, but both enzymes respond similarly to various inhibitors. 3. A similar enzyme has been found in the kidney and adrenal of rat and in the liver and kidney of numerous species. 4. The identity and the physiological role of the enzyme are discussed.