Diamide induced shift in protein and glutathione thiol: disulfide status delays DNA rejoining after X-irradiation of human cancer cells

By treating a human tumor cell line with various concentrations of diamide, we explored the relationship between extent and duration of protein and nonprotein thiol oxidation, initiation of DNA double-strand break rejoining after X-rays, and the degree of radiosensitization. We also examined the relationship between protein thiol status and the non-protein thiol, glutathione (GSH). A549 cells were irradiated and incubated postirradiation with 0, 100, 300 or 500 microM diamide for 1 h. The dose of radiation required to give 10% survival decreased from 4.8 Gy to 3.2 Gy with 300 microM and to 2.7 Gy with 500 microM diamide (enhancement ratios of 1.5 and 1.8, respectively) but was not significantly affected by 100 microM diamide. The time of initiation of double-stranded DNA rejoining after X-irradiation (DNA repair) was delayed by 300 and 500 microM diamide. Furthermore, DNA rejoining began only after total cellular protein thiol content recovered to 55% of pretreatment levels for both concentrations. Intracellular GSH/GSSG ratios decreased immediately after diamide addition to less than 1. Large decreases in GSH/GSSG ratio preceded significant loss of protein thiols, but protein-glutathione mixed disulfides accounted for a minor percentage of the total protein thiol oxidized (up to 20%). We believe that diamide-induced protein thiol loss, and not GSH oxidation, is related to the cessation of DNA strand rejoining after X-irradiation, thereby affecting survival.     

Radiosensitization by hypoxic pretreatment with misonidazole: an interaction of damage at the DNA level

Prolonged exposures to misonidazole (MISO) in vitro under hypoxic conditions result in radiosensitization which is characterized by a decrease in the size of the radiation survival curve shoulder for cells irradiated under hypoxic or aerobic conditions after drug removal. Although intracellular glutathione (GSH) was depleted during hypoxic exposures to MISO, this could not account for the dose-additive radiosensitization (decrease in shoulder size) since GSH depletion by diethylmaleate had no effect on the sensitivity of cells irradiated in air. The alkaline elution assay was used to measure DNA strand breaks and their repair after exposure to MISO, graded doses of X rays, and the combination of MISO pretreatment with X rays. The elution rate of DNA from irradiated cells increased linearly with X-ray dose, with and without MISO pretreatment. However, the DNA elution rates measured after MISO pretreatment were greater by a constant amount at all X-ray doses greater than 1 Gy. In terms of both cell survival and DNA elution rate, MISO-pretreated cells behaved as though they had received an extra 1.5 Gy. Although the initial damage after X rays was greater in MISO-pretreated cells, there was no effect of MISO pretreatment on the rate of repair of radiation-induced DNA strand breaks. The agreement between the differences in survival levels and DNA elution rates for irradiated control and MISO-pretreated cells and absence of an effect on DNA repair rates suggest that the pretreatment sensitization is due to an additive interaction of damage at the DNA level.     

Chromatographic and mass spectrometric analysis of glutathione in biological samples

Biological thiol compounds are classified into high-molecular-mass protein thiols and low-molecular-mass free thiols. Endogenous low-molecular-mass thiol compounds, namely, reduced glutathione (GSH) and its corresponding disulfide, glutathione disulfide (GSSG), are very important molecules that participate in a variety of physiological and pathological processes. GSH plays an essential role in protecting cells from oxidative and nitrosative stress and GSSG can be converted into the reduced form by action of glutathione reductase. Measurement of GSH and GSSG is a useful indicator of oxidative stress and disease risk. Many publications have reported successful determination of GSH and GSSG in biological samples. In this article, we review newly developed techniques, such as liquid chromatography coupled with mass spectrometry and tandem mass spectrometry, for identifying GSH bound to proteins, or for localizing GSH in bound or free forms at specific sites in organs and in cellular locations.     

Glutaredoxin 2 catalyzes the reversible oxidation and glutathionylation of mitochondrial membrane thiol proteins: implications for mitochondrial redox regulation and antioxidant DEFENSE

The redox poise of the mitochondrial glutathione pool is central in the response of mitochondria to oxidative damage and redox signaling, but the mechanisms are uncertain. One possibility is that the oxidation of glutathione (GSH) to glutathione disulfide (GSSG) and the consequent change in the GSH/GSSG ratio causes protein thiols to change their redox state, enabling protein function to respond reversibly to redox signals and oxidative damage. However, little is known about the interplay between the mitochondrial glutathione pool and protein thiols. Therefore we investigated how physiological GSH/GSSG ratios affected the redox state of mitochondrial membrane protein thiols. Exposure to oxidized GSH/GSSG ratios led to the reversible oxidation of reactive protein thiols by thiol-disulfide exchange, the extent of which was dependent on the GSH/GSSG ratio. There was an initial rapid phase of protein thiol oxidation, followed by gradual oxidation over 30 min. A large number of mitochondrial proteins contain reactive thiols and most of these formed intraprotein disulfides upon oxidation by GSSG; however, a small number formed persistent mixed disulfides with glutathione. Both protein disulfide formation and glutathionylation were catalyzed by the mitochondrial thiol transferase glutaredoxin 2 (Grx2), as were protein deglutathionylation and the reduction of protein disulfides by GSH. Complex I was the most prominent protein that was persistently glutathionylated by GSSG in the presence of Grx2. Maintenance of complex I with an oxidized GSH/GSSG ratio led to a dramatic loss of activity, suggesting that oxidation of the mitochondrial glutathione pool may contribute to the selective complex I inactivation seen in Parkinson's disease. Most significantly, Grx2 catalyzed reversible protein glutathionylation/deglutathionylation over a wide range of GSH/GSSG ratios, from the reduced levels accessible under redox signaling to oxidized ratios only found under severe oxidative stress. Our findings indicate that Grx2 plays a central role in the response of mitochondria to both redox signals and oxidative stress by facilitating the interplay between the mitochondrial glutathione pool and protein thiols.     

Turnover and functions of glutathione studied with isolated hepatic and renal cells

Suspensions of freshly isolated rat hepatocytes and renal tubular cells contain high levels of reduced glutathione (GSH), which exhibits half-lives of 3-5 and 0.7-1 h, respectively. In both cells types the availability of intracellular cysteine is rate limiting for GSH biosynthesis. In hepatocytes, methionine is actively converted to cysteine via the cystathionine pathway, and hepatic glutathione biosynthesis is stimulated by the presence of methionine in the medium. In contrast, extracellular cystine can support renal glutathione synthesis; several disulfides, including cystine, are rapidly taken up by renal cells (but not by hepatocytes) and are reduced to the corresponding thiols via a GSH-linked reaction sequence catalyzed by thiol transferase and glutathione reductase (NAD(P)H). During incubation, hepatocytes release both GSH and glutathione disulfide (GSSG) into the medium; the rate of GSSG efflux is markedly enhanced during hydroperoxide metabolism by glutathione peroxidase. This may lead to GSH depletion and cell injury; the latter seems to be initiated by a perturbation of cellular calcium homeostasis occurring in the glutathione-depleted state. In contrast to hepatocytes, renal cells metabolize extracellular glutathione and glutathione S-conjugates formed during drug biotransformation to the component amino acids and N-acetyl-cysteine S-conjugates, respectively. In addition, renal cells contain a thiol oxidase acting on extracellular GSH and several other thiols. In conclusion, our findings with isolated cells mimic the physiological situation characterized by hepatic synthesis and renal degradation of plasma glutathione and glutathione S-conjugates, and elucidate some of the underlying biochemical mechanisms.     

Molecular mechanisms of quinone cytotoxicity

Quinones are probably found in all respiring animal and plant cells. They are widely used as anticancer, antibacterial or antimalarial drugs and as fungicides. Toxicity can arise as a result of their use as well as by the metabolism of other drugs and various environmental toxins or dietary constituents. In rapidly dividing cells such as tumor cells, cytotoxicity has been attributed to DNA modification. However the molecular basis for the initiation of quinone cytotoxicity in resting or non-dividing cells has been attributed to the alkylation of essential protein thiol or amine groups and/or the oxidation of essential protein thiols by activated oxygen species and/or GSSG. Oxidative stress arises when the quinone is reduced by reductases to a semiquinone radical which reduces oxygen to superoxide radicals and reforms the quinone. This futile redox cycling and oxygen activation forms cytotoxic levels of hydrogen peroxide and GSSG is retained by the cell and causes cytotoxic mixed protein disulfide formation. Most quinones form GSH conjugates which also undergo futile redox cycling and oxygen activation. Prior depletion of cell GSH markedly increases the cell's susceptibility to alkylating quinones but can protect the cell against certain redox cycling quinones. Cytotoxicity induced by hydroquinones in isolated hepatocytes can be attributed to quinones formed by autoxidation. The higher redox potential benzoquinones and naphthoquinones are the most cytotoxic presumably because of their higher electrophilicty and thiol reactivity and/or because the quinones or GSH conjugates are more readily reduced to semiquinones which activate oxygen.     

The dependence of thiol-inducible radiation resistance in Escherichia coli K12 on the medium and catalytic metal

Radiation protection by thiols in procaryotes and lower eucaryotes has been demonstrated repeatedly to require a competent DNA repair phenotype, suggesting that simple chemical radical scavenging and hydrogen donation are only a portion of the mechanism of radiation protection by thiols. In the present report, thiol-induced radiation resistance--a model in which cells are pretreated with dithiothreitol and then irradiated in the absence of thiol--is shown to be a medium-dependent process. Wild-type log-phase cells treated with dithiothreitol in minimal-glucose medium are induced to radioresistance that persists after the thiol has been removed. Although the thiol pretreatment affected the antioxidants (catalase, superoxide dismutase, and glutathione) in cells at the time of irradiation, various antioxidant levels did not predict radiation resistance. Thiol-induced radioresistance is not expressed in rich medium-treated cells or in DNA repair (recA)-deficient cells. Addition of the efficient chelator, DETAPAC, to the thiol treatment medium leads to additional radioresistance in the case of minimal medium and a moderate expression of resistance in rich medium. Experiments using the intracellular chelator, 1,10-phenanthroline, in the presence of thiol led to inhibition of thiol-induced resistance in minimal medium and radiosensitization in rich medium. These results can be explained by a "site-specific" mechanism of thiol oxidation in which the chelators control the site(s) and rate of thiol oxidation, subsequently determining the type of cellular response.     

Radiation-induced damage to DNA in drug- and radiation-resistant sublines of a human breast cancer cell line.

An Adriamycin-resistant subline of a human breast cancer cell line, MCF-7 ADRR, has been shown to exhibit radioresistance associated with an increase in the size of the shoulder on the radiation survival curve. In the present study, damage to DNA of MCF-7 sublines WT and ADRR by 60Co gamma radiation was measured by filter elution techniques. The initial amount of DNA damage, measured by both alkaline and neutral filter elution, was lower in ADRR cells, suggesting that these cells are resistant to radiation-induced single- and double-strand DNA breaks. In the case of double-strand breaks the difference between WT and ADRR cells was significant only at the lower radiation doses studied (up to 100 Gy). In cells depleted of glutathione (GSH) by L-buthionine sulfoximine (BSO) treatment, ADRR cells were sensitized to radiation-induced DNA damage, while WT cells were unaffected. The rate of repair of single- and double-strand DNA breaks following radiation was the same for both sublines, and repair of radiation damage was not affected by BSO treatment in either cell line. The relative resistance of ADRR cells to initial DNA damage by radiation is the only difference so far detected at the molecular level which reflects radiation survival, and it is possible that other factors are involved in the resistance of ADRR cells to killing by radiation. Sensitization of ADRR cells to radiation-induced DNA damage by GSH depletion, although not likely to involve inhibition of GSH-dependent detoxification enzymes per se (irradiation was done at 4 degrees C), suggests that at the molecular level radioresponse in this subline is related to maintenance of GSH/GSSG redox equilibrium.     

Molecular Mechanisms of Glutaredoxin Enzymes: Versatile Hubs for Thiol–Disulfide Exchange between Protein Thiols and Glutathione

The tripeptide glutathione (GSH) and its oxidized form glutathione disulfide (GSSG) constitute a key redox couple in cells. In particular, they partner protein thiols in reversible thiol–disulfide exchange reactions that act as switches in cell signaling and redox homeostasis. Disruption of these processes may impair cellular redox signal transduction and induce redox misbalances that are linked directly to aging processes and to a range of pathological conditions including cancer, cardiovascular diseases and neurological disorders. Glutaredoxins are a class of GSH-dependent oxidoreductase enzymes that specifically catalyze reversible thiol–disulfide exchange reactions between protein thiols and the abundant thiol pool GSSG/GSH. They protect protein thiols from irreversible oxidation, regulate their activities under a variety of cellular conditions and are key players in cell signaling and redox homeostasis. On the other hand, they may also function as metal-binding proteins with a possible role in the cellular homeostasis and metabolism of essential metals copper and iron. However, the molecular basis and underlying mechanisms of glutaredoxin action remain elusive in many situations. This review focuses specifically on these aspects in the context of recent developments that illuminate some of these uncertainties.     

Glutathione depletion and formation of glutathione-protein mixed disulfide following exposure of brain mitochondria to oxidative stress

t-Butyl hydroperoxide was utilized to alter the thiol homeostasis in rat brain mitochondria. Following exposure to t-butyl hydroperoxide (50-500 microM), intramitochondrial GSH content decreased rapidly and irreversibly with a major portion of the depleted GSH being accounted for as protein-SS-Glutathione mixed disulfide. Formation of GSSG was not observed nor was efflux of GSSG or GSH from the mitochondria detected in the incubation medium. The loss of intramitochondrial GSH was accompanied by loss of protein thiols. Unlike liver mitochondria, which can reverse t-butyl hydroperoxide induced formation of GSSG, addition of 50 microM t-butyl hydroperoxide resulted in irreversible loss; indicating greater susceptibility of brain mitochondria to oxidative stress than liver mitochondria.     

Membrane thiol-disulfide status in glucose-6-phosphate dehydrogenase deficient red cells. Relationship to cellular glutathione

The behavior of glucose-6-phosphate dehydrogenase (G6PD)-deficient red cell membrane proteins upon treatment with diamide, the thiol-oxidizing agent (Kosower, N.S. et al. (1969) Biochem. Biophys. Res. Commun. 37, 593–596), was studied with the aid of monobromobimane, a fluorescent labeling agent (Kosower, N.S., Kosower, E.M., Newton, G.L. and Ranney, H.M. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 3382–3386) convenient for following membrane thiol group status. In diamide-treated G6PD-deficient red cells (and in glucose deprived normal cells), glutathione (GSH) is oxidized to glutathione disulfide (GSSG). When cellular GSH is absent, membrane protein thiols are oxidized with the formation of intrachain and interchain disulfides. Differences in sensitivity to oxidation are found among membrane thiols. In diamidetreated normal red cells, GSH is regenerated in the presence of glucose and membrane disulfides reduced. In G6PD-deficient cells, GSSG is not reduced, and the oxidative damage (disulfide formation) in the membrane not repaired. Reduction of membrane disulfides does occur after the addition of GSH to these membranes. A direct link between the thiol status of the cell membrane and cellular GSH is thereby established. GSH serves as a reductant of membrane protein disulfides, in addition to averting membrane thiol oxidation.     

Histamine chloramine reactivity with thiol compounds, ascorbate, and methionine and with intracellular glutathione

Histamine is stored in granules of mast cells and basophils and released by inflammatory mediators. It has the potential to intercept some of the HOCl generated by the neutrophil enzyme, myeloperoxidase, to produce histamine chloramine. We have measured rate constants for reactions of histamine chloramine with methionine, ascorbate, and GSH at pH 7.4, of 91 M(-1)s(-1), 195 M(-1)s(-1), and 721 M(-1)s(-1), respectively. With low molecular weight thiols, the reaction was with the thiolate and rates increased exponentially with decreasing thiol group pK(a). Comparing rate constants for different chloramines reacting with ascorbate or a particular thiol anion, these were higher when there was less negative charge in the vicinity of the chloramine group. Histamine chloramine was the most reactive among biologically relevant chloramines. Consumption of histamine chloramine and oxidation of intracellular GSH were examined for human fibroblasts. At nontoxic doses, GSH loss over 10 min was slightly greater than that with HOCl, but the cellular uptake of histamine chloramine was 5-10-fold less. With histamine chloramine, GSSG was a minor product and most of the GSH was converted to mixed disulfides with proteins. HOCl gave a different profile of GSH oxidation products, with significantly less GSSG and mixed disulfide formation. There was irreversible oxidation and losses to the medium, as observed with HOCl and other cell types. Thus, histamine chloramine shows high preference for thiols both in isolation and in cells, and in this respect is more selective than HOCl.     

Ebselen induces apoptosis in HepG(2) cells through rapid depletion of intracellular thiols

Ebselen, 2-phenyl-1,2-benzisoselenazol-3(2H)-one, is a synthetic seleno-organic compound with antioxidant capability. In the present study, we systematically examined the ability of ebselen to induce apoptosis in a human hepatoma cell line, HepG(2). Ebselen-induced apoptosis was evaluated by (i) TdT-mediated dUTP nick end labeling assay; (ii) analysis of sub-G1 cells; (iii) cell morphology, including cell size and granularity examination; and (iv) DNA gel electrophoresis. The results showed that ebselen was able to induce typical apoptosis in HepG(2) cells in a dose- and time-dependent manner. In order to explore the possible mechanisms involved in ebselen-induced apoptosis, the effect of ebselen on intracellular thiol concentrations including reduced glutathione (GSH) and protein thiols and the effect of N-acetylcysteine (NAC) and buthionine sulfoximine (BSO) pretreatment on ebselen-induced apoptosis were investigated. It was found that (i) ebselen rapidly depleted intracellular GSH and protein thiols, moreover, the depletion preceded the occurrence of apoptosis; (ii) NAC, a precursor of intracellular GSH synthesis, significantly alleviated ebselen-induced apoptosis; and (iii) BSO, a specific inhibitor of intracellular GSH synthesis, augmented ebselen-induced apoptosis significantly. Taken together, the present study demonstrates that ebselen is able to induce apoptosis in HepG(2) cells, most probably through rapid depletion of intracellular thiols.     

Intermediate Mr cytosolic components potentiate hepatic 5''-deiodinase activation by thiols.

The role in the activation of microsomal 5'-deiodinase (5'-DI) of rat hepatic cytosolic components of Mr approx. 13,000 (Fraction B) was studied in the presence of various concentrations of thiol compounds such as dithiothreitol (DTT), dihydrolipoamide (DHLA), GSH, and 2-mercaptoethanol (2-ME). Although Fraction B (which was prepared by gel filtration to exclude GSH and GSSG) had no intrinsic 5'-DI activity, could not stimulate microsomal 5'-DI activity in the absence of added thiol and did not contain GSH as a mixed disulphide, it could produce a 3-fold increase in the maximal deiodinase activity achievable with DTT as well as other thiols, with the order being the same as the activation potency of these thiols in the absence of Fraction B (i.e. DHLA greater than DTT greater than 2-ME greater than GSH). These observations suggest that: a component of cytosolic Fraction B, designated 'deiodination factor B' (DFB), operates as an efficient intermediary to enhance activation of microsomal 5'-DI by thiols through a mechanism independent of GSH; thiols may participate in a non-specific thiol-disulphide exchange with inactive (oxidized) DFB to convert it into an active form that contains one or more thiol groups and is more effective than GSH or other thiols in facilitating the re-activation of inactive (oxidized) microsomal 5'-DI thiol (ESI) to its active state (ESH).     

Modulation of Cell Surface Protein Free Thiols: A Potential Novel Mechanism of Action of the Sesquiterpene Lactone Parthenolide

Background

There has been much interest in targeting intracellular redox pathways as a therapeutic approach for cancer. Given recent data to suggest that the redox status of extracellular protein thiol groups (i.e. exofacial thiols) effects cell behavior, we hypothesized that redox active anti-cancer agents would modulate exofacial protein thiols.

Methodology/Principal Findings

To test this hypothesis, we used the sesquiterpene lactone parthenolide, a known anti-cancer agent. Using flow cytometry, and western blotting to label free thiols with Alexa Fluor 633 C₅ maleimide dye and N-(biotinoyl)-N-(iodoacetyl) ethylendiamine (BIAM), respectively, we show that parthenolide decreases the level of free exofacial thiols on Granta mantle lymphoma cells. In addition, we used immuno-precipitation techniques to identify the central redox regulator thioredoxin, as one of the surface protein thiol targets modified by parthenolide. To examine the functional role of parthenolide induced surface protein thiol modification, we pretreated Granta cells with cell impermeable glutathione (GSH), prior to exposure to parthenolide, and showed that GSH pretreatment; (a) inhibited the interaction of parthenolide with exofacial thiols; (b) inhibited parthenolide mediated activation of JNK and inhibition of NFκB, two well established mechanisms of parthenolide activity and; (c) blocked the cytotoxic activity of parthenolide. That GSH had no effect on the parthenolide induced generation of intracellular reactive oxygen species supports the fact that GSH had no effect on intracellular redox. Together these data support the likelihood that GSH inhibits the effect of parthenolide on JNK, NFκB and cell death through its direct inhibition of parthenolide''s modulation of exofacial thiols.

Conclusions/Significance

Based on these data, we postulate that one component of parthenolide''s anti-lymphoma activity derives from its ability to modify the redox state of critical exofacial thiols. Further, we propose that cancer cell exofacial thiols may be important and novel targets for therapy.     

Therapeutic efficacy of green tea polyphenols on cellular thiols in 4-Nitroquinoline 1-oxide-induced oral carcinogenesis

In cancer, a high flux of oxidants not only depletes the cellular thiols, but damages the whole cell as well. Epidemiological studies suggest green tea may mitigate cancers in human and animal models for which several mechanisms have been proposed. In the present investigation, the levels of cellular thiols such as reduced glutathione (GSH), oxidised glutathione (GSSG), protein thiols (PSH), total thiols, lipid peroxidation product conjugated dienes and the activity of gamma glutamyl transferase (GGT) were assessed in tongue and oral cavity. In 4-Nitroquinoline 1-oxide- (4-NQO) induced rats, there was a decrease in the levels of GSH, PSH and total thiols and an increase in the levels of GSSG, conjugated dienes and the activity of GGT. On supplementation of green tea polyphenols (GTP) for 30 days (200 mg/kg) for the oral cancer-induced rats, there was a moderate increase in the levels of GSH, PSH and total thiols and a decrease in the levels of GSSG, conjugated dienes and the activity of GGT. Thus, GTP reduces the oxidant production thereby maintains the endogenous low molecular weight cellular thiols in oral cancer-induced rats. From the results, it can be concluded that GTP supplementation enhances the cellular thiol status thereby mitigate oral cancer.     

Glutathione redox state regulates mitochondrial reactive oxygen production

Oxidative stress induced by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD; dioxin) is poorly understood. Following one dose of TCDD (5 microg/kg body weight), mitochondrial succinate-dependent production of superoxide and H2O2 in mouse liver doubled at 7-28 days, then subsided by day 56; concomitantly, levels of GSH and GSSG increased in both cytosol and mitochondria. Cytosol displayed a typical oxidative stress response, consisting of diminished GSH relative to GSSG, decreased potential to reduce protein-SSG mixed disulfide bonds (type 1 thiol redox switch) or protein-SS-protein disulfide bonds (type 2 thiol redox switch), and a +10 mV change in GSSG/2GSH reduction potential. In contrast, mitochondria showed a rise in reduction state, consisting of increased GSH relative to GSSG, increases in type 1 and type 2 thiol redox switches, and a -25 mV change in GSSG/2GSH reduction potential. Comparing Ahr(-/-) knock-out and wild-type mice, we found that TCDD-induced thiol changes in both cytosol and mitochondria were dependent on the aromatic hydrocarbon receptor (AHR). GSH was rapidly taken up by mitochondria and stimulated succinate-dependent H2O2 production. A linear dependence of H2O2 production on the reduction potential for GSSG/2GSH exists between -150 and -300 mV. The TCDD-stimulated increase in succinate-dependent and thiol-stimulated production of reactive oxygen paralleled a four-fold increase in formamidopyrimidine DNA N-glycosylase (FPG)-sensitive cleavage sites in mitochondrial DNA, compared with a two-fold increase in nuclear DNA. These results suggest that TCDD produces an AHR-dependent oxidative stress in mitochondria, with concomitant mitochondrial DNA damage mediated, at least in part, by an increase in the mitochondrial thiol reduction state.     

The role of glutathione in the aerobic radioresponse. I. Sensitization and recovery in the absence of intracellular glutathione

The effect of changes in both the intracellular glutathione (GSH) concentration and the concentration of extracellular reducing equivalents on the aerobic radiosensitization was studied in three cell lines: CHO-10B4, V79, and A549. Intracellular GSH was metabolically depleted after the inhibition of GSH synthesis by buthionine sulfoximine (BSO), while the extracellular environment was controlled through the replacement of growth medium with a thiol-free salt solution and in some experiments by the exogenous addition of either GSH or GSSG. Each of the cell lines examined exhibited an enhanced aerobic radioresponse when the intracellular GSH was extensively depleted (GSH less than 1 nmol GSH/10(6) cells after 1.0 mM BSO/24 h treatment) and the complexity of the extracellular milieu decreased. Although the addition of oxidized glutathione (5 mM GSSG/30 min) to cells prior to irradiation was without effect, much or all of the induced radiosensitivity was overcome by the addition of reduced glutathione (5 mM GSH/15 min). However, the observation that the exogenous GSH addition restores the control radioresponse without increasing the intracellular GSH concentration was entirely unexpected. These results suggest that a number of factors exert an influence on the extent of GSH depletion and determine the extent of aerobic radiosensitization. Furthermore, the interaction of exogenous GSH with--but without penetrating--the cell membrane is sufficient to result in radiorecovery.     

Oxidative stress alters membrane sulfhydryl status, lipid and phospholipid contents of crossbred cattle bull spermatozoa

Ferrous ascorbate (FeAA: FeSO4+ascorbic acid) has been used in the past by different investigators to induce oxidative stress. The optimum dose of FeAA for inducing oxidative stress by affecting thiols [total thiols (TSH), glutathione reduced (GSH), glutathione oxidized (GSSG), redox ratio (GSH/GSSG)], total lipids and phospholipids has been ascertained in the local crossbred cattle bull spermatozoa. The fractions of spermatozoa suspended in 2.9% sodium citrate were subjected to three doses of FeAA (100 microM:500 microM, 150 microM:750 microM, 200 microM:1000 microM; FeSO4:ascorbic acid), and were assessed for various parameters. On increasing the concentration of FeAA, a gradual decrease in TSH, GSH, GSH/GSSG, lipid and phospholipid levels, but increase in GSSG content were observed. It is concluded that thiol groups play an important role in antioxidation and detoxification of ROS as well as maintaining intracellular redox status. Thiol groups, thus, serve as defense mechanisms of sperm cells to fight against oxidative stress. In addition, all doses of FeAA cause leakage of lipids and phospholipids from the bull sperm membranes.     

The pro-oxidant role of protein SH groups of hemoglobin in rat erythrocytes exposed to menadione.

Menadione is selectively toxic to erythrocytes. Although GSH is considered a primary target of menadione, intraerythrocyte thiolic alterations consequent to menadione exposure are only partially known. In this study alterations of GSH and protein thiols (PSH) and their relationship with methemoglobin formation were investigated in human and rat red blood cells (RBC) exposed to menadione. In both erythrocyte types, menadione caused a marked increase in methemoglobin associated with GSH depletion and increased oxygen consumption. However, in human RBC, GSH formed a conjugate with menadione, whereas, in rat RBC it was converted to GSSG, concomitantly with a loss of protein thiols (corresponding to menadione arylation), and an increase in glutathione-protein mixed disulfides (GS-SP). Such differences were related to the presence of highly reactive cysteines, which characterize rat hemoglobin (cys beta125). In spite of the greater thiol oxidation in rat than in human RBC, methemoglobin formation and the rate of oxygen consumption elicited by menadione in both species were rather similar. Moreover, in repeated experiments under N2 or CO-blocked heme, it was found that menadione conjugation (arylation) in both species was not dependent on the presence of oxygen or the status of heme. Therefore, we assumed that GSH (human RBC) and protein (rat RBC) arylation was equally responsible for increased oxygen consumption and Hb oxidation. Moreover, thiol oxidation of rat RBC was strictly related to methemoglobin formation.