Activation of rat liver microsomal glutathione S-transferase by hydrogen peroxide: role for protein-dimer formation.

The mechanism of oxygen radical-dependent activation of hepatic microsomal glutathione S-transferase by hydrogen peroxide was studied. Glutathione S-transferase activity in liver microsomes was increased 1.5-fold by incubation with 0.75 mM hydrogen peroxide at 37 degrees C for 10 min, and the increase in activity was reversed by incubation with dithiothreitol. Purified glutathione S-transferase was also activated by hydrogen peroxide after incubation at room temperature, and the increase in the activity was also reversed by dithiothreitol. Immunoblotting with anti-microsomal glutathione S-transferase antibodies after sodium dodecyl sulfate-polyacrylamide gel electrophoresis of hydrogen peroxide-treated microsomes or purified glutathione S-transferase revealed the presence of a glutathione S-transferase dimer. These results indicate that the hydrogen peroxide-dependent activation of the microsomal glutathione S-transferase is associated with the formation of a protein dimer.     

Effect of selenium deficiency and vitamin E deficiency on glutathione metabolism in isolated rat hepatocytes

Selenium deficiency and vitamin E deficiency both affect xenobiotic metabolism and toxicity. In addition, selenium deficiency causes changes in the activity of some glutathione-requiring enzymes. We have studied glutathione metabolism in isolated hepatocytes from selenium-deficient, vitamin E-deficient, and control rats. Cell viability, as measured by trypan blue exclusion, was comparable for all groups during the 5-h incubation. Freshly isolated hepatocytes had the same glutathione concentration regardless of diet group. During the incubation, however, the glutathione concentration in selenium-deficient hepatocytes rose to 1.4 times that in control hepatocytes. The selenium-deficient cells also released twice as much glutathione into the incubation medium as did the control cells. Total glutathione (intracellular plus extracellular) in the incubation flask increased from 47.7 +/- 8.9 to 152 +/- 16.5 nmol/10(6) selenium-deficient cells over 5 h compared with an increase from 46.7 +/- 7.1 to 92.0 +/- 17.4 nmol/10(6) control cells and from 47.7 +/- 11.7 to 79.5 +/- 24.9 nmol/10(6) vitamin E-deficient cells. This overall increase in glutathione concentration suggested that glutathione synthesis was accelerated by selenium deficiency. The activity of gamma-glutamylcysteine synthetase was twice as great in selenium-deficient liver supernatant (105,000 X g) as in vitamin E-deficient or control liver supernatant (105,000 X g). Hemoglobin-free perfused livers were used to determine the form of glutathione released and its route. Selenium-deficient livers released 4 times as much GSH into the caval perfusate as did control livers. Plasma glutathione concentration in selenium-deficient rats was found to be 2-fold that in control rats, suggesting that increased GSH synthesis and release is an in vivo phenomenon associated with selenium deficiency.     

Glutathione Turnover in Cultured Astrocytes: Studies with [15N]Glutamate

The incorporation of [15N]glutamic acid into glutathione was studied in primary cultures of astrocytes. Turnover of the intracellular glutathione pool was rapid, attaining a steady state value of 30.0 atom% excess in 180 min. The intracellular glutathione concentration was high (20-40 nmol/mg protein) and the tripeptide was released rapidly into the incubation medium. Although labeling of glutathione (atom% excess) with [15N]glutamate occurred rapidly, little accumulation of 15N in glutathione was noted during the incubation compared with 15N in aspartate, glutamine, and alanine. Glutathione turnover was stimulated by incubating the astrocytes with diethylmaleate, an electrophile that caused a partial depletion of the glutathione pool(s). Diethylmaleate treatment also was associated with significant reductions of intraastrocytic glutamate, glycine, and cysteine, i.e., the constituents of glutathione. Glutathione synthesis could be stimulated by supplementing the steady-state incubation medium with 0.05 mM L-cysteine, such treatment again partially depleting intraastrocytic glutamate and causing significant reductions of 15N labeling of both alanine and glutamine, suggesting that glutamate had been diverted from the synthesis of these amino acids and toward the formation of glutathione. The current study underscores both the intensity of glutathione turnover in astrocytes and the relationship of this turnover to the metabolism of glutamate and other amino acids.     

Regulation of prolyl endopeptidase activity by the intracellular redox state

The activity of prolyl endopeptidase was markedly decreased during incubation of intact murine erythroleukemia cells at 45 degrees C, but not during incubation of sonicated cells or during incubation at 42 degrees C. The thermal inactivation of prolyl endopeptidase in situ required neither the synthesis of proteins and polynucleotides nor the synergistic activation of inhibitors. Moreover, inhibition of lysosomal proteinases and calpains or depletion of ATP did not affect the thermal inactivation of prolyl endopeptidase. This specific inactivation of prolyl endopeptidase was also observed following the addition to the culture medium of menadione or diamide, compounds known to increase intracellular oxidized glutathione levels. The activity of prolyl endopeptidase in the cell lysate was also dose-dependently decreased by the addition of glutathione disulfide and the decrease of the activity was prevented by coexistence of reduced glutathione. Furthermore, the level of intracellular oxidized glutathione was increased during incubation at 45 degrees C for 15 min, but not at 42 degrees C for 30 min. These results strongly suggest that the activity of prolyl endopeptidase is regulated by changes in the intracellular redox potential.     

The effect of cytochrome P-450 and reduced glutathione on the ATP-dependent calcium pump of hepatic microsomes from male rats

In the presence of ATP hepatic microsomes sequester calcium. This sequestration is thought to be important in the modulation of free cytosolic calcium concentration. We find that on the addition of NADPH the uptake of calcium by the hepatic microsomes is inhibited 27-85%. This inhibition is reversed by the addition of 1 mM reduced glutathione (85-91% of control), incubation under a nitrogen atmosphere (112% of control), or incubation in a 80% carbon monoxide/20% oxygen atmosphere (75% of control). Superoxide dismutase had no effect on the inhibition, while catalase reversed the inhibition by 35%. The addition of 1 mM reduced glutathione at 2 and 5 min after the addition of NADPH led to uptakes of calcium which paralleled the uptake seen when the reduced glutathione was added at the beginning of the incubation. The effect of reduced glutathione showed saturation kinetics with a Km of 10 microM. Together these data suggest that cytochrome P-450 reduces the activity of the microsomal ATP-dependent calcium pump both by the production of hydrogen peroxide and by the direct oxidation of the protein thiols. The reversal of this effect by reduced glutathione appears to be enzymatically catalyzed.     

4-Hydroxynonenal inhibits glutathione peroxidase: protection by glutathione.

4-Hydroxy-2,3-trans-nonenal, a lipid peroxidation product, inhibits glutathione peroxidase in a concentration-dependent manner. The concentration providing 50% inhibition is 0.12 mM. This inhibition can be almost completely (89%) prevented by 1 mM glutathione added to the incubation mixture 30 min before 4-hydroxy-2,3-trans-nonenal or 2,3-trans-nonenal, but not by other thiol-containing antioxidants such as 0.5 mM dithiothreitol or beta-mercaptoethanol. Again the addition of 1 mM glutathione, and not of 0.5 mM dithiothreitol or beta-mercaptoethanol, to the enzyme 30 min after incubation with 4-hydroxy-2,3-trans-nonenal restores activity to the same extent as does the preincubation with GSH. In view of the known reactivity of 4-hydroxy-2,3-trans-nonenal with lysine residues and the reversibility of the inhibition, the involvement of a lysine residue in GSH binding to glutathione peroxidase is proposed. The potential relevance of the inhibition of glutathione peroxidase by 4-hydroxy-nonenal to oxidative tissue damage is discussed with particular emphasis on neurological disorders.     

Extracellular calcium protects isolated rat hepatocytes from injury

The incubation of isolated rat hepatocytes in calcium-free medium resulted in a pronounced increase in lipid peroxidation, mitochondrial and cytoplasmic glutathione depletion, glutathione disulfide formation and efflux of reduced glutathione as compared with hepatocytes incubated in calcium containing medium. These data suggest that extracellular calcium ions serve a protective role in isolated rat hepatocytes against cell injury.     

External GSSG enhances intracellular glutathione level in isolated cardiac myocytes

The addition of external GSSG at concentrations in the range 50-500 microM produces in isolated adult rat heart myocytes an increase of GSH level and only a slight increase of GSSG level. On the contrary, external GSH at the above same indicated concentrations did not change the cell glutathione pool. The pretreatment of the cells with diethylamaleate depleted the myocytes of glutathione and enhanced the GSSG-induced replenishment effect on GSH level. On the contrary, the addition of GSH did not increase the concentration of cell glutathione. The level of cell GSH in diethylmaleate-treated myocytes was not increased after 30 min of incubation with cysteine, or acetylcysteine. The GSSG induced-stimulation on GSH level was not inhibited by buthionine sulfoximine, an inhibitor of glutathione synthesis. On the contrary, this stimulatory effect was inhibited by N, N-bis(2-chloroethyl)-N-nitrosourea, an inhibitor of glutathione reductase, or partially, by the remotion of glucose from the incubation medium. These results support the idea that the isolated adult rat heart myocytes are able to utilize external GSSG in order to increase the intracellular glutathione pool, probably through the reduction of the imported GSSG to GSH.     

Subcellular glutathione contents in isolated hepatocytes treated with L-buthionine sulfoximine

The glutathione contents of the mitochondrial and cytosolic fractions and extracellular space of isolated hepatocytes decrease when glutathione synthesis is inhibited with L-buthionine sulfoximine. Mitochondrial glutathione is depleted to 50% of its initial value whereas the cytosolic pool is completely emptied after 2 h incubation in the presence of inhibitor. The mitochondrial glutathione content was only fully depleted when L-buthionine sulfoximine was added together with phorone (2,6-dimethyl-2,5-heptadiene-4-one), a substrate of the glutathione S-transferases (E.C. 2.5.1.18).     

Effect of cholesterol and 7beta-hydroxycholesterol on glutathione status and expression of Hsp70 in cultured murine peritoneal macrophages

Using cultured murine peritoneal macrophages, the change in redox ratio (oxidized/reduced glutathione) was studied at different incubation intervals (6, 12, 18 and 24 hr) with different concentrations (2.5, 5 and 7.5 microg/ml) of cholesterol and 7beta-hydroxycholesterol (7beta-OH), using fluorimeter. The changes in the levels of heat shock protein, hsp70 was determined using ELISA. Both cholesterol/7beta-OH caused a decrease in hsp70 protein levels at all the incubation intervals in dose dependent manner but the decrease was significantly higher with 7beta-OH. Treatment with 7beta-OH also resulted in significantly increased levels of oxidized glutathione (GSSG) and decreased reduced glutathione (GSH) while cholesterol showed no effect on GSSG levels. Moreover, GSH levels were lowered only at the highest concentration (7.5 microg/ml) at longer incubation intervals (18 and 24 hr) with cholesterol exposure. This altered the redox status in both cholesterol/7beta-OH treated macrophages. These results suggest that cholesterol and more likely 7beta-OH may exert their pro-atherogenic effects by lowering hsp70 protein production and inhibiting glutathione synthesis by macrophages present in the arterial wall.     

Hydrogen-peroxide-induced heme degradation in red blood cells: the protective roles of catalase and glutathione peroxidase

Catalase and glutathione peroxidase (GSHPX) react with red cell hydrogen peroxide. A number of recent studies indicate that catalase is the primary enzyme responsible for protecting the red cell from hydrogen peroxide. We have used flow cytometry in intact cells as a sensitive measure of the hydrogen-peroxide-induced formation of fluorescent heme degradation products. Using this method, we have been able to delineate a unique role for GSHPX in protecting the red cell from hydrogen peroxide. For extracellular hydrogen peroxide, catalase completely protected the cells, while the ability of GSHPX to protect the cells was limited by the availability of glutathione. The effect of endogenously generated hydrogen peroxide in conjunction with hemoglobin autoxidation was investigated by in vitro incubation studies. These studies indicate that fluorescent products are not formed during incubation unless the glutathione is reduced to at least 40% of its initial value as a result of incubation or by reacting the glutathione with iodoacetamide. Reactive catalase only slows down the depletion of glutathione, but does not directly prevent the formation of these fluorescent products. The unique role of GSHPX is attributed to its ability to react with hydrogen peroxide generated in close proximity to the red cell membrane in conjunction with the autoxidation of membrane-bound hemoglobin.     

The Detoxification of Cumene Hydroperoxide by the Glutathione System of Cultured Astroglial Cells Hinges on Hexose Availability for the Regeneration of NADPH

The ability of astroglia-rich primary cultures derived from the brains of newborn rats to detoxify exogenously applied cumene hydroperoxide (CHP) was analyzed as a model to study glutathione-mediated peroxide detoxification by astrocytes. Under the conditions used, 200 microM CHP disappeared from the incubation buffer with a half-time of approximately 10 min. The half-time of CHP in the incubation buffer was found strongly elevated (a) in cultures depleted of glutathione by a preincubation with buthionine sulfoximine, an inhibitor of glutathione synthesis, (b) in the presence of mercaptosuccinate, an inhibitor of glutathione peroxidase, and (c) in the absence of glucose, a precursor for the regeneration of NADPH. The involvement of glutathione peroxidase in the clearance of CHP was confirmed by the rapid increase in the level of GSSG after application of CHP. The restoration of the initial high ratio of GSH to GSSG depended on the presence of glucose during the incubation. The high capacity of astroglial cells to clear CHP and to restore the initial ratio of GSH to GSSG was fully maintained when glucose was replaced by mannose. In addition, fructose and galactose at least partially substituted for glucose, whereas exogenous isocitrate and malate were at best marginally able to replace glucose during peroxide detoxification and regeneration of GSH. These results demonstrate that CHP is detoxified rapidly by astroglial cells via the glutathione system. This metabolic process strongly depends on the availability of glucose or mannose as hydride donors for the regeneration of the NADPH that is required for the reduction of GSSG by glutathione reductase.     

Thiol/disulfide redox equilibrium and kinetic behavior of chicken liver fatty acid synthase

Chicken liver fatty acid synthase is rapidly inactivated and cross-linked at pH 7.2 and 8.0 by incubation with low concentrations of common biological disulfides including glutathione disulfide, coenzyme A disulfide, and glutathione-coenzyme A-mixed disulfide. Glutathione disulfide inactivation of the enzyme is accompanied by the oxidation of a total of 4-5 enzyme thiols per monomer. Only one glutathione equivalent is incorporated per monomer as a protein-mixed disulfide, and its rate of incorporation is significantly slower than the rate of inactivation. The formation of protein-SS-protein disulfides results in significant cross-linking of enzyme subunits. The inactive enzyme is rapidly and completely reactivated, and the cross-linking is completely reversed by incubation of the enzyme with thiols (10-20 mM) including dithiothreitol, mercaptoethanol, and glutathione. In a glutathione redox buffer (GSH + GSSG), disulfide bond formation comes to equilibrium. The enzyme activity at equilibrium is dependent both on the ratio of glutathione to glutathione disulfide and on the total glutathione concentration. The equilibrium constant for the redox equilibration of fatty acid synthase in a glutathione redox buffer is 15 mM (Ered + GSSG in equilibrium Eox + 2GSH). The formation of at least one protein-protein disulfide per monomer dominates the redox properties of the enzyme while the formation of one protein-mixed disulfide with glutathione (Kmixed = 0.45) has little effect on activity. The oxidation equilibrium constant suggests that there would be no significant cycling between the reduced and the oxidized enzyme in response to likely physiological variations in the hepatic glutathione status. The possibility that changes in the concentration of cellular glutathione may act as a mechanism for metabolic control of other enzymes is discussed.     

γ-Glutamylcysteinylserine — A New Homologue of Glutathione in Plants of the Family Poaceae*

In addition to glutathione (γ-GluCysGly), many species of the family Poaceae have another tripeptide which has the amino acid sequence γ-GluCysSer. This thiol was isolated from etiolated leaves of wheat (Triticum aestivum L. cv. Star). Its structure was elucidated by quantitative amino acid analysis after total hydrolysis and by partial hydrolysis with carboxypeptidase A and γ-glutamyltranspeptidase. The content of γ-GluCysSer in the leaves of T. aestivum is increased by incubation with sulfate and is severely diminished by incubation with buthionine sulfoximine, a specific inhibitor of γ-glutamylcysteine synthetase. Oxidized γ-GluCysSer is reduced by yeast glutathione reductase with a rate somewhat lower than for glutathione, but the new tripeptide is not a substrate of glutathione-S-transferase from equine liver. Besides homoglutathione (γ-GluCysßAla), a tripeptide found in plants of the order Fabales, the tripeptide γ-GluCysSer is the second homologue of glutathione detected in plants.     

Human genetic defect in leukotriene C4 synthesis

Normal human platelets metabolise [3H]-LTA4 into [3H]-LTC4. Platelets from patients with glutathione synthetase deficiency possessing 10-30% of normal levels of cellular glutathione showed marked reduction in capacity to form [3H]-LTC4 (8-10% of normal) even though exogenous reduced glutathione was added to the incubation medium. To our knowledge this is the first demonstration of a genetic defect in LTC4 synthetase coupled to a defect in cellular glutathione levels.     

Characteristics of chloramine complexes of carnosine with hypochlorite anion]

Carnosine interaction with CIO results in the formation of a stable chloramine complex. The binding of the whole bulk of hypochlorite to carnosine is completed within one minute of incubation. During subsequent 2-hour incubation no more than 15% of the chloramine complex is destroyed; this property of carnosine makes it similar to taurine. Unlike histidine and beta-alanine, glutathione rapidly interacts with hypochlorite. However, in contrast with these compounds and carnosine, glutathione does not form stable chloramine complexes with CIO. The putative role of myeloperoxidase in the development of senile human lens opacities is discussed.     

13C NMR spectroscopic measurement of glutathione synthesis and antioxidant metabolism in the intact ocular lens.

A 13C NMR spectroscopic method for non-invasive, time-resolved measurements of glutathione function in the intact ocular lens maintained in organ culture is described. L-[beta-13C]cysteine (1 mM) included in the incubation medium is incorporated, by way of lenticular amino acid uptake and glutathione biosynthetic mechanisms, into the cysteinyl residue of intralenticular glutathione. 13C-NMR chemical shift measurements facilitate analysis of glutathione synthesis and anti-oxidant reactions in the intact tissue. The results of this preliminary study demonstrate the viability of a rapid non-invasive method for monitoring the multiple aspects of glutathione biosynthesis, metabolism, and function in intact tissue.     

Use of the inhibition of enzymatic antioxidant systems in order to evaluate their physiological importance

Chemical inhibitors of the different antioxidant enzymes were systematically testet either on purified enzymes of after incubation with human fibroblasts in culture. Inhibition values were obtained for catalase with aminotriazole, for superoxide dismutase with diethyldithiocarbamate, for glutathione peroxidase with mercaptosuccinate, for glutathione reductase with bischloroethylnitrosourea and for glutathione synthesis with buthionine sulfoximine. Viability of cells incubated with these inhibitors was then tested under normal conditions and under high oxygen pressure; the data were correlated with the above-mentioned inhibitory values. Cell viability was particularly affected when the glutathione-related enzymes, especially glutathione peroxidase, were inhibited.     

Involvement of the cystathionine pathway in the biosynthesis of glutathione by isolated rat hepatocytes

The ability of l-methionine to support glutathione biosynthesis has been investigated in isolated rat hepatocytes under conditions of normal and depleted glutathione status. The addition of l-[³⁵S]methionine or [l-[³⁵S]homocysteine to incubation media containing hepatocytes results in the incorporation of ³⁵S into intracellular glutathione. Additionally both l-methionine and l-homocysteine are capable of supporting the resynthesis of glutathione in isolated hepatocytes after prior depletion with diethyl maleate. The inclusion in the incubation medium of 1 mm propargylglycine, which is an irreversible inhibitor of the terminal enzyme of the cystathionine pathway, substantially blocks the incorporation of ³⁵S from methionine and l-homocysteine into cellular glutathione. Propargylglycine treatment of hepatocytes in the presence of [³⁵S]methionine is shown to result in the intracellular accumulation of [³⁵S]cystathionine. These results strongly support the conclusion that in rat hepatocytes the cystathionine pathway enables methionine to provide a significant source of l-cysteine for the support of glutathione biosynthesis, under both normal and glutathione-depleted conditions.     

The Glutathione System of Peroxide Detoxification Is Less Efficient in Neurons than in Astroglial Cells

The ability of neurons to detoxify exogenously applied peroxides was analyzed using neuron-rich primary cultures derived from embryonic rat brain. Incubation of neurons with H2O2 at an initial concentration of 100 microM (300 nmol/3 ml) led to a decrease in the concentration of the peroxide, which depended strongly on the seeding density of the neurons. When 3 x 10(6) viable cells were seeded per dish, the half-time for the clearance by neurons of H2O2 from the incubation buffer was 15.1 min. Immediately after application of 100 microM H2O2 to neurons, glutathione was quickly oxidized. After incubation for 2.5 min, GSSG accounted for 48% of the total glutathione. Subsequent removal of H2O2 caused an almost complete regeneration of the original ratio of GSH to GSSG within 2.5 min. Compared with confluent astroglial cultures, neuron-rich cultures cleared H2O2 more slowly from the incubation buffer. However, if the differences in protein content were taken into consideration, the ability of the cells to dispose of H2O2 was identical in the two culture types. The clearance rate by neurons for H2O2 was strongly reduced in the presence of the catalase inhibitor 3-aminotriazol, a situation contrasting with that in astroglial cultures. This indicates that for the rapid clearance of H2O2 by neurons, both glutathione peroxidase and catalase are essential and that the glutathione system cannot functionally compensate for the loss of the catalase reaction. In addition, the protein-normalized ability of neuronal cultures to detoxify exogenous cumene hydroperoxide, an alkyl hydroperoxide that is reduced exclusively via the glutathione system, was lower than that of astroglial cells by a factor of 3. These results demonstrate that the glutathione system of peroxide detoxification in neurons is less efficient than that of astroglial cells.