Showing papers on "Glutathione published in 1988"

Protective role of glutathione and glutathione transferases in mutagenesis and carcinogenesis.

Abstract: Glutathione (GSH) alone detoxifies electrophiles with an effectiveness which depends on the rate of the reaction and the concentration of GSH. If electrophiles are substrates for GSH transferase isoenzymes, the effectiveness of detoxication is much enhanced due to the increased rate of reaction and it is also independent of GSH concentration to low levels of GSH depletion, since the K m for GSH is approximately 0.1 mM. In this paper detoxication of electrophilic metabolites of the hepatocarcinogen N -methyl-4-aminoazobenzene which are not substrates for GSH transferases and the carcinogenic electrophile derived from the hepatocarcinogen aflatoxin B 1 which is a poor substrate is compared with detoxication of electrophiles which are good substrates and which although bacterial mutagens are not carcinogenic in organs containing the appropriate GSH transferases. GSH transferases detoxify not only electrophiles derived from xenobiotics, but also endogenous electrophiles which are usually the consequence of free radical damage in the presence of oxygen to lipids and DNA and include lipid and DNA hydroperoxides and alkenals arising from the decomposition of lipid hydroperoxides. Studies in the rat and other mammals show the GSH transferases to be dimers in which the subunits are members of a gene super-family. There are three, perhaps four multigene families namely, alpha containing subunits 1, 2, 8 and 10; mu containing subunits 3, 4 6 and 9; pi containing subunit 7 and subunits 5 and 5 ∗ which are so far unassigned. Subunit 5 ∗ is apparently restricted to the nucleus and is noteworthy for its activity towards DNA hydroperoxides. Studies in the human are not as advanced as in the rat but so far reveal close similarities. The ability of GSH transferases to detoxify electrophiles is important in carcinogenesis at a number of points. They may inhibit initiation and tumour proportion, but they may be advantageous to the developing tumour cell, and may be acquired in increased amounts during malignant progression. In many tumour cells the development of lines resistant to anticancer drugs is associated with an increased expression of GSH transferases, particularly GSH transferase π in human cells.

The protection by ascorbate and glutathione against microsomal lipid peroxidation is dependent on vitamin E

Abstract: Lipid peroxidation of rat liver microsomal fractions was monitored by its low-level chemilunminescence in preparations from controls and vitamin-E-deficient animals. Measurements were made (a) of the duration of the lag phase τ0 after initiation with NADPH/iron-ADP and (b) of the slope of the chemiluminescence increase. In microsomes with normal vitamin E (α-tocopherol) level the lag phase τ0 was substantially increased by ascorbate; in contrast, even an enhanced peroxidation was observed with ascorbate in vitamin-E-deficient microsomes. Therefore, the ascorbate-mediated protection of microsomal membranes against lipid peroxidation is dependent on vitamin E in the membrane. In vitamin E deficiency the pro-oxidant effect of ascorbate was abolished when glutathione (GSH) was present. Likewise, GSH does not prolong the lag phase τ0 in vitamin E deficiency. However, GSH (but not cysteine) exerts an antioxidant effect both in controls and in vitamin E deficiency by decreasing the slope of the chemiluminescence increase during lipid peroxidation. The involvement of GSH in an enzyme-dependent mechanism is suggested.

Glutathione causes a massive and selective induction of plant defense genes.

Abstract: The reduced form of glutathione (GSH), when supplied to suspension cultured cells of bean (Phaseolus vulgaris L.) at concentrations in the range 0.01 to 1.0 millimolar, stimulates transcription of defense genes including those that encode cell wall hydroxyproline-rich glycoproteins and the phenylpropanoid biosynthetic enzymes phenylalanine ammonialyase (PAL) and chalcone synthase (CHS) involved in lignin (PAL) and phytoalexin (PAL, CHS) production. Transcriptional activation of these genes leads to marked accumulation of the corresponding transcripts, contributing to a massive change in the overall pattern of protein synthesis which closely resembles that previously observed in response to fungal elicitor. GSH causes a marked increase in extractable PAL activity, whereas the oxidized form of glutathione, constituent amino acids, or other reducing agents are inactive. Possible roles of GSH in signaling biological stress are discussed.

Intracellular binding and transport of hormones and xenobiotics by glutathione-S-transferases.

Abstract: (1988). Intracellular Binding and Transport of Hormones and Xenobiotics by Glutathiones-Transferases. Drug Metabolism Reviews: Vol. 19, No. 3-4, pp. 305-318.

Blood glutathione oxidation during human exercise

Abstract: To examine the effects of increased O2 utilization on the glutathione antioxidant system in blood, eight moderately trained male volunteers were exercised to peak O2 consumption (VO2peak) and for 9...

Glutathione deficiency in alcoholics: risk factor for paracetamol hepatotoxicity.

Abstract: Patients chronically abusing ethanol are more susceptible to the hepatotoxic effects of paracetamol. This could be due to an increased activation of the drug to a toxic metabolite or to a decreased capacity to detoxify the toxic metabolite by conjugation with glutathione (GSH). To test these hypotheses paracetamol 2 g was administered to five chronic alcoholics without clinical evidence of alcoholic liver disease and five control subjects. The urinary excretion of cysteine- plus N-acetyl-cysteine-paracetamol, the two major products of detoxification of the reactive metabolite of paracetamol, was not significantly higher in chronic alcoholics arguing against a substantially increased metabolic activation of paracetamol. Chronic alcoholics had significantly lower plasma concentrations of GSH than healthy volunteers, however (4.35 (1.89) microM v 8.48 (2.68) microM, p less than 0.05) before the administration of paracetamol, and plasma GSH reached lower concentrations in the alcoholics after paracetamol (2.40 (1.36) v 6.26 (2.96) microM). In a group of patients with alcoholic hepatitis intrahepatic GSH was significantly lower than in patients with chronic persistent hepatitis and patients with non-alcoholic cirrhosis, suggesting that low plasma GSH in alcoholics reflects low hepatic concentrations of GSH. The data indicate that low GSH may be a risk factor for paracetamol hepatotoxicity in alcoholics because a lower dose of paracetamol will be necessary to deplete GSH below the critical threshold concentration where hepatocellular necrosis starts to occur.

Reactive oxygen species during ischemia-reflow injury in isolated perfused rat liver.

Abstract: The hypothesis that intracellular generation of reactive oxygen species in hepatocytes or reticuloendothelial cells may cause ischemia-reperfusion injury was tested in isolated perfused livers of male Fischer rats. GSSG was measured in perfusate, bile, and tissue as a sensitive index of oxidative stress. After a preperfusion phase of 30 min, the perfusion was stopped (global ischemia) for various times (30, 120 min) and the liver was reperfused for another 60 min. The bile flow (1.48 +/- 0.17 microliters/min X gram liver weight), the biliary efflux of total glutathione (6.54 +/- 0.94 nmol GSH eq/min X g), and GSSG (1.59 +/- 0.23 nmol GSH eq/min X g) recovered to 69-86% after short-term ischemia and to 36-72% after 2 h of ischemia when compared with values obtained from control livers perfused for the same period of time. During reperfusion, the sinusoidal efflux of total glutathione (16.4 +/- 2.1 nmol GSH eq/min X g) and GSSG (0.13 +/- 0.05 nmol GSH eq/min X g) did not change except for an initial 10-30-s increase during reperfusion washout. No increased GSSG secretion into bile was detectable at any time during reperfusion. The liver content of total glutathione (32.5 +/- 3.5 nmol GSH eq/mg protein) and GSSG (0.27 +/- 0.09 nmol GSH eq/mg protein) did not change significantly during any period of ischemia or reperfusion. We conclude, therefore, that at most only a minor amount of reactive oxygen species were generated during reperfusion. Thus, reactive oxygen species are unlikely to cause ischemia/reperfusion injury in rat liver by lipid peroxidation or tissue thiol oxidation.

Glutathione and glutathione-dependent enzymes in ovarian adenocarcinoma cell lines derived from a patient before and after the onset of drug resistance: intrinsic differences and cell cycle effects

Abstract: The regulation of glutathione and various glutathione-dependent enzymes has been studied in two ovarian adenocarcinoma cell lines derived from a patient before (PE01) and after (PE04) the onset of drug resistance to cis-platinum, chlorambucil and 5-fluorouracil. Reduced glutathione levels were higher in the drug resistant cells (PE04). This could possibly be attributed to a much higher (6.5-fold) gamma-glutamyl-transpeptidase activity. In addition, glutathione-S-transferase (GST) and glutathione peroxidase were 2.9- and 2.3-fold higher in this cell line. Analysis of the GST subunit composition showed both cell lines contained high levels of the acidic GST and lower concentrations of a basic isozyme. The difference in GST activity between PE01 and PE04 did not appear to be related to the levels of these GST subunits. GSH, glutathione peroxidase and gamma-glutamylcysteinyl synthetase were all found to be regulated during the cell cycle, higher levels being detected in logarithmic versus confluent cultures of PE01 and PE04 and MCF7. This did affect some of the differences between PE01 and PE04 and therefore may be a contributing factor to the differential sensitivity of these cells to cytotoxic compounds. The above data provide the first evidence that tumour cells obtained from a patient before and after the onset of drug resistance have significant differences in glutathione-dependent enzyme content.

Antioxidant enzyme alterations in experimental and clinical diabetes.

Abstract: Previous studies from our laboratory have demonstrated the presence of complex alterations in the activities of antioxidant enzymes in various tissues of rats with streptozotocin (STZ)-induced diabetes. In the present investigation, it is shown that rats made diabetic with alloxan (ALX), an agent differing from STZ both chemically and in its mechanism of diabetogenesis, show virtually identical tissue antioxidant enzyme changes which, as is the case with STZ, are preventable by insulin treatment. The finding that the patterns of antioxidant enzyme alterations in chemically-induced diabetes are independent of the diabetogenic agent used and the presence of similar abnormalities in tissues of spontaneously diabetic (BB) Wistar rats (particularly when diabetic control is less than optimal) suggest that the changes observed are a characteristic feature of the uncontrolled diabetic state and that these may be responsible for (or predispose to) the development of secondary complications in clinical diabetes. Comparative studies involving red cells of diabetic rats and human diabetics revealed a number of common changes, namely an increase in glutathione reductase activity, a decreased susceptibility to oxidative glutathione depletion (which was related to the presence of hyperglycemia) and an increased production of malondialdehyde (an indirect index of lipid peroxidation) in response to in vitro challenge with hydrogen peroxide. In the diabetic patients, the extent of this increase in susceptibility of red cell lipids to oxidation paralleled the severity of diabetic complications. Our results suggest that increased (or uncontrolled) oxidative activity may play an important role in the pathogenesis of complications associated with the chronic diabetic state.

Biosynthesis and biotransformation of glutathione S-conjugates to toxic metabolites.

Abstract: The material presented in this review deals with the hypothesis that the nephrotoxicity of certain halogenated alkanes and alkenes is associated with hepatic biosynthesis of glutathione S-conjugates, which are further metabolized to the corresponding cysteine S-conjugates. Some glutathione or cysteine S-conjugates may be direct-acting nephrotoxins, but most cysteine S-conjugates require bioactivation by renal, pyridoxal phosphate-dependent enzymes, such as cysteine conjugate beta-lyase (beta-lyase). The biosynthesis of glutathione S-conjugates is catalyzed by both the cytosolic and the microsomal glutathione S-transferases, although the latter enzyme is a better catalyst for the reaction of haloalkenes with glutathione. When glutathione S-conjugate formation yields sulfur mustards, as occurs with vicinal-dihaloethanes, the S-conjugates are direct-acting toxins. In contrast, the S-conjugates formed from fluoro- and chloroalkenes yield S-alkyl- or S-vinyl glutathione conjugates, respectively, which are metabolized to the corresponding cysteine S-conjugates by gamma-glutamyltransferase and dipeptidases; inhibition of these enzymes blocks the toxicity of the glutathione S-conjugates. The cysteine S-conjugates must be metabolized by beta-lyase for the expression of toxicity; the beta-lyase inhibitor aminooxyacetic acid blocks the toxicity of cysteine S-conjugates, and the corresponding alpha-methyl cysteine S-conjugates, which cannot be metabolized by beta-lyase, are not toxic. Moreover, probenecid, an inhibitor of renal anion transport system, blocks the toxicity of cysteine S-conjugates, which cannot be metabolized by beta-lyase, are not toxic. Moreover, probenecid, an inhibitor of renal anion transport system, blocks the toxicity of cysteine S-conjugates. Homocysteine S-conjugates are also potent cyto- and nephrotoxins. The high renal content of gamma-glutamyltransferase and the renal anion transport system are probably determinants of kidney tissue as a target site. Biochemical studies indicate that renal mitochondrial dysfunction is produced by the cysteine S-conjugates. Finally, some of the glutathione and cysteine conjugates are mutagenic in the Ames test, and reactive intermediates formed by the action of beta-lyase may contribute to the nephrocarcinogenicity of certain chloroalkenes.

Role of glutathione

Abstract: Radicals produced by X-rays may react with oxygen, producing intermediates that are believed to be toxic to cells. We propose a hypothesis that glutathione (GSHi may protect against radiation damage in four ways, as shown in Figure 1. GSH can react with hydroxyl radicals, organic radicals, and peroxyl radicals, and is a substrate for enzymatic reduction of hydro peroxides and peroxides. Based on this model, we used the GSH-synthesis inhibitor L-buthionine sulfoximine (LBSO) to deplete cell~lar GSH in order to determine its importance in radiation response. Results showed that GSH

The retention mechanism of technetium-99m-HM-PAO: intracellular reaction with glutathione.

Abstract: Preparations of d,l- and meso-hexamethylpropyleneamine oxime (HM-PAO) labeled with technetium-99m were added to rat brain homogenates diluted with phosphate buffer (1:10). The conversion of d,l-HM-PAO to hydrophilic forms took place with an initial rate constant of 0.12 min-1. Incubation of the brain homogenate with 2% diethyl maleate for 5 h decreased the homogenate's measured glutathione (GSH) concentration from 160 to 16 microM and decreased the conversion rate to 0.012 min-1. Buffered aqueous solutions of glutathione rapidly converted the HM-PAO tracers to hydrophilic forms having the same chromatographic characteristics as found in the brain homogenates. The rate constant for the conversion reaction of d,l-HM-PAO in GSH aqueous solution was 208 and 317 L/mol/min in two different assay systems and for meso-HM-PAO the values were 14.7 and 23.2 L/mol/min, respectively. Rat brain has a GSH concentration of about 2.3 mM and the conversion of the d,l-HM-PAO due to GSH alone should proceed with a rate constant of 0.48 to 0.73 min-1 and be correspondingly 14-fold slower for meso-HM-PAO. In human brain, the in vivo data of Lassen et al. show a conversion rate constant of 0.80 min-1. This correspondence of values supports the notion that GSH may be important for the inmore » vivo conversion of 99mTc-labeled HM-PAO to hydrophilic forms and may be the mechanism of trapping in brain and other cells. A kinetic model for the trapping of d,l- and meso-HM-PAO in tissue is developed that is based on data of GSH concentration in various organs.« less

Sequential oxidation and glutathione addition to 1,4-benzoquinone: correlation of toxicity with increased glutathione substitution.

Abstract: The chemical reaction of 1,4-benzoquinone with glutathione results in the formation of adducts that exhibit increasing degrees of glutathione substitution. Purification of these adducts and analysis by 1H and 13C nuclear magnetic resonance spectroscopy revealed the products of the reaction to be 2-(glutathion-S-yl)hydroquinone; 2,3-(diglutathion-S-yl)hydroquinone; 2,5-(diglutathion-S-yl)hydroquinone; 2,6(diglutathion-S-yl)hydroquinone; 2,3,5-(triglutathion-S-yl)hydroquinone; and 2,3,5,6-(tetraglutatathion-S-yl)hydroquinone. The initial conjugation of 1,4-benzoquinone with glutathione did not significantly affect the oxidation potential of the compound. However, subsequent oxidation and glutathione addition resulted in the formation of conjugates that, dependent upon the position of addition, become increasingly more difficult to oxidize. Increased glutathione substitutions, which resulted in an increase in oxidation potentials, paradoxically resulted in enhanced nephrotoxicity. The triglutathion-S-yl conjugate was the most potent nephrotoxicant; the diglutathion-S-yl conjugates exhibited similar degrees of nephrotoxicity; the mono- and tetraglutathion-S-yl conjugates were not toxic. Thus, with the exception of the fully substituted isomer, the severity of renal necrosis correlated with the extent of glutathione substitution. The lack of toxicity of the fully substituted isomer is probably a consequence of its inability to alkylate tissue components. Thus, the conjugation of glutathione with quinones does not necessarily result in detoxification, even when the resulting conjugates are more stable to oxidation. The inhibition of gamma-glutamyl transpeptidase by AT-125 protected against 2,3,5-(triglutathion-S-yl)hydroquinone-mediated nephrotoxicity. It is suggested that other extra-renal sites expressing relatively high levels of gamma-glutamyl transpeptidase might therefore also be susceptible to hydroquinone-linked glutathione conjugate toxicity. This pathway might also contribute to the carcinogenicity and mutagenicity of certain quinones.

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

Abstract: 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.

Synthesis and in vitro toxicity of hydroxylamine metabolites of sulfonamides.

Abstract: Among the most serious side effects of sulfonamides are hypersensitivity reactions, the pathogenesis of which has been suggested to be mediated by reactive metabolites. We have previously demonstrated dose-related covalent binding and toxicity of reactive intermediates of sulfonamides generated by a murine hepatic microsomal activating system. We hypothesized that hydroxylamine (H/A) metabolites might be likely candidates for mediating such toxicity; accordingly, we synthesized chemically the H/As of sulfadiazine and sulfamethoxazole. Synthesis was performed using 4-nitrobenzenesulfonyl chloride and either 2-aminopyrimidine or 3-amino-5-methylisoxazole, respectively, as starting materials. The resulting nitro derivatives were reduced to the corresponding H/A with hydrogen in the presence of a poisoned platinum catalyst. After synthesis and purification, toxicity of the H/As to lymphocytes of normal volunteers was evaluated using three cytotoxicity assays: 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide dye conversion, trypan blue dye exclusion and propidium iodide dye exclusion. The H/As of sulfadiazine and sulfamethoxazole displayed dose-related toxicity. 1.6 mM sulfadiazine H/A produced 82% cell death, whereas 400 microM sulfamethoxazole H/A produced 62% cell death; the parent sulfonamides were not toxic to cells. The toxicity of sulfamethoxazole H/A was decreased by coincubation with glutathione or N-acetylcysteine; there was a 47% decrease in toxicity when coincubated with 100 microM glutathione, whereas there was a 55% decrease displayed when coincubation was done with 500 microM N-acetylcysteine. H/A metabolites of the sulfonamides or their nitroso derivatives, normally detoxified by conjugation to glutathione, may be the proximate toxins mediating sulfonamide hypersensitivity.