Formation of mixed disulfide of cystatin-beta in cultured macrophages treated with various oxidants

Macrophage cell cultures were treated with menadione, zymosan, or phorbol myristate acetate (PMA), and changes in productions of superoxide anion and hydroperoxide, and in glutathione oxidation and S-thiolation of cystatin-beta (formation of a mixed disulfide of cystatin-beta and glutathione) were examined. All three compounds promoted production of superoxide anion and hydroperoxide, but only menadione caused extensive oxidation of glutathione. Menadione caused S-thiolation of cystatin-beta in a dose-dependent fashion, but the other two compounds did not. Removal of menadione promptly reduced the oxidation of glutathione and S-thiolation of cystatin-beta induced by menadione. Inhibition of catalase by aminotriazol caused slight increase in the GSSG content in both menadione- and zymosan-treated cells, but not in S-thiolation of cystatin-beta in zymosan-treated cells. None of the three compounds influenced appreciably the activity of glutathione peroxidase, glutathione reductase, or superoxide dismutase in cultured cells. These results indicate that S-thiolation of cystatin-beta occurs in cells in response to oxidative challenge by menadione but not by zymosan or by the tumor promoter PMA. Dethiolation of cystatin-beta by purified thiol transferase and protein disulfide isomerase in the presence of different concentrations of GSH was examined in vitro. Both enzymes catalyzed dethiolation of cystatin-beta at a much lower level of GSH than that required for the non-enzymatic reaction, suggesting the importance of enzymatic catalysis of S-thiolation and dethiolation of cystatin-beta in cells.     

Inhibition of biliary taurocholate excretion during menadione metabolism in perfused rat liver

In perfused rat liver menadione elicits substantial oxidation in both the NADPH and GSH redox systems. Biliary excretion of GSSG is increased several-fold. Menadione derivatives appear in the bile predominantly as the menadione-S-glutathione conjugate, thiodione (60%), or as conjugates derived therefrom (17%). About 10% appear as menadione glucuronides. The excretion of taurocholate into bile is strongly inhibited upon menadione infusion. The inhibition of taurocholate excretion is small in livers with a low content of Se-GSH-peroxidase and in glutathione-depleted livers. In these livers intracellular GSSG and biliary GSSG release remain at low values, although menadione still imposes oxidative stress as indicated by an oxidation of intracellular NADPH. Under anoxic conditions menadione has little influence on both the NADPH and GSH redox systems and also on biliary taurocholate excretion. The amount of thiodione released into bile is similar to that found under normoxia, whereas the amount of glucuronidated products almost doubled. We conclude (a) that intracellular formation of GSSG by menadione occurs via the generation of hydrogen peroxide; (b) that the inhibition of biliary taurocholate excretion by menadione is related to the increased formation of glutathione disulfide; and (c) that menadione derivatives show little, if any, contribution to the inhibition of taurocholate excretion.     

Glutathionyl- and hydroxyl radical formation coupled to the redox transitions of 1,4-naphthoquinone bioreductive alkylating agents during glutathione two-electron reductive addition.

The kinetic parameters of the redox transitions subsequent to the two-electron transfer implied in the glutathione (GSH) reductive addition to 2- and 6-hydroxymethyl-1,4-naphthoquinone bioalkylating agents were examined in terms of autoxidation, GSH consumption in the arylation reaction, oxidation of the thiol to glutathione disulfide (GSSG), and free radical formation detected by the spin-trapping electron spin resonance method. The position of the hydroxymethyl substituent in either the benzenoid or the quinonoid ring differentially influenced the initial rates of hydroquinone autoxidation as well as thiol oxidation. Thus, GSSG- and hydrogen peroxide formation during the GSH reductive addition to 6-hydroxymethyl-1,4-naphthoquinone proceeded at rates substantially higher than those observed with the 2-hydroxymethyl derivative. The distribution and concentration of molecular end products, however, was the same for both quinones, regardless of the position of the hydroxymethyl substituent. The [O2]consumed/[GSSG]formed ratio was above unity in both cases, thus indicating the occurrence of autoxidation reactions other than those involved during GSSG formation. EPR studies using the spin probe 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) suggested that the oxidation of GSH coupled to the above redox transitions involved the formation of radicals of differing structure, such as hydroxyl and thiyl radicals. These were identified as the corresponding DMPO adducts. The detection of either DMPO adduct depended on the concentration of GSH in the reaction mixture: the hydroxyl radical adduct of DMPO prevailed at low GSH concentrations, whereas the thiyl radical adduct of DMPO prevailed at high GSH concentrations. The production of the former adduct was sensitive to catalase, whereas that of the latter was sensitive to superoxide dismutase as well as to catalase. The relevance of free radical formation coupled to thiol oxidation is discussed in terms of the thermodynamic and kinetic properties of the reactions involved as well as in terms of potential implications in quinone cytotoxicity.     

Modulation of benzoquinone-induced cytotoxicity by diethyldithiocarbamate in isolated hepatocytes

The copper-chelating thiol drug diethyldithiocarbamate protected isolated hepatocytes from benzoquinone-induced alkylation cytotoxicity by reacting with benzoquinone and forming a conjugate which was identified by fast atom bombardment mass spectrometry as 2-(diethyldithiocarbamate-S-yl) hydroquinone. In contrast to benzoquinone, the conjugate was not cytotoxic to isolated hepatocytes. The thiol reductant dithiothreitol had no effect on benzoquinone-induced alkylation cytotoxicity. However, inactivation of catalase in the hepatocytes with azide and addition of the reducing agent ascorbate markedly enhanced the cytotoxicity of the conjugate but did not affect benzoquinone-induced cytotoxicity. Furthermore, inactivation of glutathione reductase and catalase in hepatocytes greatly enhanced the cytotoxicity of the conjugate and caused oxidation of GSH to GSSG. The conjugate also stimulated cyanide-resistant respiration, which suggests that the conjugate undergoes futile redox cycling resulting in the formation of hydrogen peroxide which causes cytotoxicity in isolated hepatocytes only if the peroxide detoxifying enzymes are inactivated. Diethyldithiocarbamate does, however, protect uncompromised isolated hepatocytes from benzoquinone cytotoxicity by conjugating benzoquinone, thereby preventing the electrophile from alkylating essential macromolecules. Diethyldithiocarbamate therefore changed the initiating cytotoxic mechanism of benzoquinone from alkylation to oxidative stress, which was less toxic.     

Actin S-glutathionylation: evidence against a thiol-disulphide exchange mechanism

Many proteins, including actin, are targets for S-glutathionylation, the reversible formation of mixed disulphides between protein cysteinyl thiol groups and glutathione (GSH) that can be induced in cells by oxidative stress. Proposed mechanisms of protein S-glutathionylation follow mainly two distinct pathways. One route involves the initial oxidative modification of a reduced protein thiol to an activated protein, which may then react with GSH to the mixed disulphide. The second route involves the oxidative modification of GSH to an activated form such as glutathione disulphide (GSSG), which may then react with a reduced protein thiol, yielding the corresponding protein mixed disulphide. We show here that physiological levels of GSSG induce a little extent of actin S-glutathionylation. Instead, actin with the exposed cysteine thiol activated by diamide or 5,5'-dithiobis(2-nitrobenzoic acid) reacts with physiological levels of GSH, incorporating about 0.7 mol GSH/mol protein. Differently, an extremely high concentration of GSSG induces an increased level of S-glutathionylation that causes a 50% inhibition in actin polymerization not reversed by dithiotreitol. In mammalian cells, GSH is present in millimolar concentrations and is in about 100-fold excess over GSSG. The high concentration of GSSG required for obtaining a significant actin S-glutathionylation as well as attendant irreversible changes in protein functions make unlikely that actin may be S-glutathionylated by a thiol-disulphide exchange mechanism within the cell.     

The interaction of reduced glutathione with active oxygen species generated by xanthine-oxidase-catalyzed metabolism of xanthine

The interaction of reduced glutathione (GSH) with active oxygen species generated during xanthine-oxidase-catalyzed metabolism of xanthine was investigated. The only GSH-derived product detected in this system was oxidized glutathione (GSSG). Catalase inhibited the oxidation of GSH to GSSG by more than 80%, whereas superoxide dismutase exerted a smaller but significant inhibition of GSSG formation. Hydroxyl radical (OH) scavengers or desferrioxamine (1 mM) had no effect on GSSG formation. Using EPR spectroscopy and the spin trap 5,5-dimethylpyrroline-N-oxide (DMPO), the production of superoxide was observed by the detection of a DMPO-OOH radical adduct. This spectrum was altered by the inclusion of GSH (5 - 20 mM) in the reaction mixture, indicating the generation of a different radical species consistent with DMPO-glutathionyl radical adduct generation.     

Effects of glutathione reductase inhibition on cellular thiol redox state and related systems

Although inhibition of glutathione reductase (GR) has been demonstrated to cause a decrease in reduced glutathione (GSH) and increase in glutathione disulfide (GSSG), a systematic study of the effects of GR inhibition on thiol redox state and related systems has not been noted. By employing a monkey kidney cell line as the cell model and 2-acetylamino-3-[4-(2-acetylamino-2-carboxy-ethylsulfanylthio carbonylamino)phenylthiocarbamoylsulfanyl]propionic acid (2-AAPA) as a GR inhibitor, an investigation of the effects of GR inhibition on cellular thiol redox state and related systems was conducted. Our study demonstrated that, in addition to a decrease in GSH and increase in GSSG, 2-AAPA increased the ratios of NADH/NAD⁺ and NADPH/NADP⁺. Significant protein glutathionylation was observed. However, the inhibition did not affect the formation of reactive oxygen species or expression of antioxidant defense enzyme systems [GR, glutathione peroxidase, catalase, and superoxide dismutase] and enzymes involved in GSH biosynthesis [γ-glutamylcysteine synthetase and glutathione synthetase].     

Effect of flooding on the activities of some enzymes of activated oxygen metabolism,the levels of antioxidants,and lipid peroxidation in senescing tobacco leaves

Effects of flooding on the activities of some enzymes of activated oxygen metabolism, the levels of antioxidants, and lipid peroxidation in senescing leaves of tobacco were investigated. As judged by the decrease in chlorophyll and protein levels, flooding accelerated the senescence of tobacco leaves. Total peroxide and the lipid peroxidation product, malondialdehyde, increased in both control and flooding-treated leaves with increasing duration of the experiment. Throughout the duration of the experiment, flooded leaves had higher levels of total peroxide and malondialdehyde than did control leaves. Flooding resulted in an increase in peroxidase and ascorbate peroxidase activities and a reduction of superoxide dismutase activity in the senescing leaves. Glycolate oxidase, catalase, and glutathione reductase activities were not affected by flooding. Flooding increased the levels of total ascorbate and dehydroascorbate. Total glutathione, reduced form glutathione, or oxidized glutathione levels in flooded leaves were lower than in control leaves during the first two days of the experiment, but were higher than in control leaves at the later stage of the experiment. Our work suggests that senescence of tobacco induced by flooding may be a consequence of lipid peroxidation possibly controlled by superoxide dismutase activity. Our results also suggest that increased rates of hydrogen peroxide in leaves of flooded plants could lead to increased capacities of the scavenging system of hydrogen peroxide.Abbreviations GSH reduced form glutathione - GSSG oxidized form glutathione - GSSG reductase glutathione reductase - MDA malondialdehyde - SOD superoxide dismutase     

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.     

Cellular effects of N(4-ethoxyphenyl)p-benzoquinone imine, a p-phenetidine metabolite formed during peroxidase reactions

The interaction of N-(4-ethoxyphenyl)p-benzoquinone imine (NEPBQI), a metabolite formed during peroxidase catalyzed metabolism of p-phenetidine, with GSH and its effects in isolated rat hepatocytes were investigated.

When reacted with GSH NEPBQI formed both a mono- and a diglutathione conjugate as well as GSSG. Formation of glutathione conjugates and GSSG also occurred when NEPBQI was added to isolated hepatocytes. The formation of GSSG was, however, only detectable if the hepatocytes had been pretreated with the GSSG reductase inhibitor BCNU (1,3-bis-(2-chloroethyl-1-nitrosourea).

Similarly, NEPBQI caused a rapid decrease in cellular free protein thiols when added to hepatocytes, however this was expressed at higher concentrations than for effects on GSH. The protein thiol decrease was correlated with protein binding of NEPBQI.

NEPBQI was also shown to be toxic to isolated hepatocytes. At a concentration of 400 μM extensive bleb formation was followed by loss of cell membrane integrity and cell death.

To assess further the subcellular metabolism of NEPBQI microsomes and cytosol was used. NEPBQI was found to be preferentially reduced by cytochrome P-450 reductase in the microsomes whereas DT-diaphorase catalyzed its reduction in cytosol. NEPBQI did not undergo significant redox cycling since no formation of O was observed. Thus, the cytotoxic effect of NEPBQI appears to be due to protein arylation rather than redox cycling.     

Evaluation of a dithiocarbamate derivative as a model of thiol oxidative stress in H9c2 rat cardiomyocytes

Thiol redox state (TRS) refers to the balance between reduced thiols and their corresponding disulfides and is mainly reflected by the ratio of reduced and oxidized glutathione (GSH/GSSG). A decrease in GSH/GSSG, which reflects a state of thiol oxidative stress, as well as thiol modifications such as S-glutathionylation, has been shown to have important implications in a variety of cardiovascular diseases. Therefore, research models for inducing thiol oxidative stress are important tools for studying the pathophysiology of these disease states as well as examining the impact of pharmacological interventions on thiol pathways. The purpose of this study was to evaluate the use of a dithiocarbamate derivative, 2-acetylamino-3-[4-(2-acetylamino-2-carboxyethylsulfanylthiocarbonylamino)phenylthiocarbamoylsulfanyl]propionic acid (2-AAPA), as a pharmacological model of thiol oxidative stress by examining the extent of thiol modifications induced in H9c2 rat cardiomyocytes and its impact on cellular functions. The extent of thiol oxidative stress produced by 2-AAPA was also compared to other models of oxidative stress including hydrogen peroxide (H₂O₂), diamide, buthionine sulfoximine, and N,N׳-bis(2-chloroethyl)-N-nitroso-urea. Results indicated that 2-AAPA effectively inhibited glutathione reductase and thioredoxin reductase activities and decreased the GSH/GSSG ratio by causing a significant accumulation of GSSG. 2-AAPA also increased the formation of protein disulfides as well as S-glutathionylation. The alteration in TRS led to a loss of mitochondrial membrane potential, release of cytochrome c, and increase in reactive oxygen species production. Compared to other models, 2-AAPA is more potent at creating a state of thiol oxidative stress with lower cytotoxicity, higher specificity, and more pharmacological relevance, and could be utilized as a research tool to study TRS-related normal and abnormal biochemical processes in cardiovascular diseases.     

Effects of menadione and hydrogen peroxide on glutathione status in growing Escherichia coli

Menadione (MD) and H2O2 caused distinct effects on glutathione status in growing Escherichia coli. Treatment of E. coli AB1157 with 1-25 mM H2O2 did not result in an appreciable decrease in intracellular total glutathione (reduced glutathione [GSH] + oxidized glutathione [GSSG]). Only when cells were treated with 25 mM H2O2 an increase in GSSG and a decrease in the GSH:GSSG ratio were observed. In cells deficient in catalase HPI, such effect was observed even at 10 mM H2O2. The exposure of E. coli AB1157 to MD caused a dose-dependent decrease in intracellular total glutathione, an increase in GSSG, and a decrease in the ratio of GSH:GSSG. In E. coli deficient in cytosolic superoxide dismutase activity, a decrease in total glutathione after incubation with 0.2 mM MD was not accompanied by an increase in GSSGin, and the ratio of GSHin:GSSGin was three times higher than in the wild-type cells. The changes in the redox status of extracellular glutathione under the action of both oxidants were similar. Although the catalase activity increased several times after exposure to both oxidants, there were little or no changes in the activity of enzymes related to glutathione metabolism. A possible role of changes in redox status of glutathione under oxidative stress is discussed.     

Simultaneous quantitative determination of alloxan, GSH and GSSG by HPlc. Estimation of the frequency of redox cycling between alloxan and dialuric acid.

This in vitro study compares the frequency of redox cycling between alloxan and dialuric acid at different initial ratios of glutathione and alloxan. Alloxan oxidizes GSH to GSSG. The rate of GSH oxidation at a given initial GSH concentration of 2.0 mmol/L depends on the initial concentration of alloxan added. The higher the concentration of alloxan in relation to the initial concentration of GSH, the faster GSH oxidation proceeds, as well as oxygen consumption, and therefore, formation of reactive oxygen species. The highest rates of GSH oxidation, i.e. GSSG formation, were found at concentration ratios of between 2.0 mmol/L GSH and 0.2 and 0.04 mmol/L alloxan, respectively. Because 0.04 mmol/L alloxan oxidizes 2.0 mmol/L GSH completely, a frequency of at least 25 cycles between alloxan and dialuric acid within 3 hours can be assumed. During each redox cycle, two molecules of GSH are oxidized to one molecule of GSSG, and during each cycle one molecule of oxygen is reduced simultaneously to one molecule of hydrogen peroxide. In total, therefore, one molecule of alloxan oxidizes at least 50 molecules of GSH and forms about 25 molecules of hydrogen peroxide.     

The reaction of menadione with haemoglobin. Mechanism and effect of superoxide dismutase.

1. Menadione was found to react with both the haem groups and the beta-93 thiol groups of haemoglobin. 2. It oxidized the haem groups of oxyhaemoglobin, giving mainly methaemoglobin and a smaller amount of haemichrome. The reaction rate was decrease in the presence of catalase and markedly accelerated in the presence of superoxide dismutase. It is proposed that the overall reaction involves the initial reversible formation of methaemoglobin and the semiquinone, and that the effect of superoxide dismutase is to prevent the reverse reaction, by removing superoxide and hene O2-. E.s.r. evidence for the information of the semi-quinone and its reactions is presented. 3. The reaction of menadione with the beta-93 thiol groups of haemoglobin appeared to be similar to that with other thiols, forming the 3-thioether derivative of menadione, but it was also accompanied by reduction of methaemoglobin. This reduction was prevented by superoxide dismutase, but appeared to be caused by the semiquinone radical, which was produced as an intermediate. 4. Reduced glutathione functioned only to a limited extent as a scavenger of the menadione semiquinone. Its main reaction was directly with menadione to form the thioether. Ascorbate was a more efficient scavenger, and accelerated the oxidation of oxyhaemoglobin by menadione. 5. The significance of these findings in relation to menadione-induced erythrocyte haemolysis is discussed.     

Influence of glutathione on the reactivation of enzymes containing cysteine or cystine

Refolding of dimeric porcine cytosolic or mitochondrial malate dehydrogenases and of tetrameric pig heart and skeletal muscle lactate dehydrogenases (containing 5-7 cysteine residues), as well as reformation of the four cystine cross-bridges of bovine pancreatic ribonuclease, were studied in the presence of reduced and oxidized glutathione (GSH and GSSG). At the intracellular GSH level (5 mM) reduced ribonuclease can be reoxidized by 0.01-0.5 mM GSSG (pH 7.4) both at 20 degrees C and 37 degrees C. In this physiological range of GSSG concentrations and pH, the dehydrogenases show at least partial reactivation. With GSSG concentrations greater than 5 mM, reactivation is found to be completely inhibited for all the enzymes given. The results show that at the intracellular level of GSH and GSSG, thiol groups in reduced, unfolded ribonuclease are oxidized to form intramolecular cystine cross-bridges, while thiol groups of typical cysteine enzymes, such as lactate and malate dehydrogenase, remain in their reduced state during refolding. The rate of reactivation of lactate dehydrogenase (porcine muscle) is not affected by GSSG. In the case of ribonuclease, increasing concentrations of GSSG increase the rate of reactivation: At 20 degrees C, the halftime of the correct disulfide bond formation varies from approximately equal to 80 h in the presence of 0.01 mM GSSG to approximately equal to 10 h in the presence of 0.25 mM GSSG. A further increase in the rate of reactivation at higher GSSG concentrations is accompanied by a decrease in yield. Reactivation of ribonuclease is also observed at the low glutathione level found in blood plasma (5-25 microM GSH).     

Glutathione reductase plays an anti-apoptotic role against oxidative stress in human hepatoma cells

The cellular roles of glutathione reductase (GR) in the reactive oxygen species (ROS)-induced apoptosis were studied using the HepG2 cells transfected with GR. The overexpression of GR caused a marked enhancement in reduced and oxidized glutathione (GSH/GSSG) ratio, and significantly decreased ROS levels in the stable transfectants. Hydrogen peroxide (H₂O₂), under the optimal condition for apoptosis, significantly decreased cellular viability and total GSH content, and rather increased ROS level, apoptotic percentage and caspase-3 activity in the mock-transfected cells. However, hydrogen peroxide could not largely generate these apoptotic changes in cellular viability, ROS level, apoptotic percentage, caspase-3 activity and total GSH content in the cells overexpressing GR. Taken together, GR may play a protective role against oxidative stress.     

Oxidation of glutathione and reduced pyridine nucleotides by the myotoxic and mutagenic aromatic amine, 1,2,4-triaminobenzene

The myotoxic and mutagenic aromatic amine, 1,2,4-triaminobenzene, has been shown to oxidise glutathione and reduced pyridine nucleotides in a cyclic reaction which generates both superoxide radical and hydrogen peroxide. It is suggested that the process is initiated by the triaminobenzene radical, formed by autoxidation of the amine. This, by mediating the one-electron oxidation of GSH and NAD(P)H, is able to establish a radical chain-reaction leading to the formation of GSSG and NAD(P)+. This reaction may be of significance in the pathogenesis of the toxic effects of 1,2,4-triaminobenzene, not only by forming reactive free-radicals but also by compromising cellular defences against oxidative attack.     

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.     

Alterations in intracellular thiol homeostasis during the metabolism of menadione by isolated rat hepatocytes

The effects of menadione (2-methyl-1,4-naphthoquinone) metabolism on intracellular soluble and protein-bound thiols were investigated in freshly isolated rat hepatocytes. Menadione was found to cause a dose-dependent decrease in intracellular glutathione (GSH) level by three different mechanisms: (a) Oxidation of GSH to glutathione disulfide (GSSG) accounted for 75% of the total GSH loss; (b) About 15% of the cellular GSH reacted directly with menadione to produce a GSH-menadione conjugate which, once formed, was excreted by the cells into the medium; (c) A small amount of GSH (approximately 10%) was recovered by reductive treatment of cell protein with NaBH4, indicating that GSH-protein mixed disulfides were also formed as a result of menadione metabolism. Incubation of hepatocytes with high concentrations of menadione (greater than 200 microM) also induced a marked decrease in protein sulfhydryl groups; this was due to arylation as well as oxidation. Binding of menadione represented, however, a relatively small fraction of the total loss of cellular sulfhydryl groups, since it was possible to recover about 80% of the protein thiols by reductive treatments which did not affect protein binding. This suggests that the loss of protein sulfhydryl groups, like that of GSH, was mainly a result of oxidative processes occurring within the cell during the metabolism of menadione.     

S-glutathionylation in human platelets by a thiol-disulfide exchange-independent mechanism

Protein-glutathione mixed disulfide formation was investigated in vitro by exposure of human platelets to the thiol-specific oxidant azodicarboxylic acid-bis-dimethylamide (diamide). We found that diamide causes a decrease in the reduced form of glutathione (GSH), paralleled by an increase in protein-GSH mixed disulfides (S-glutathionylated proteins), which was not accompanied by any significant increase in the basal level of glutathione disulfide (GSSG). The increase in the appearance of S-glutathionylated proteins was inversely correlated with ADP-induced platelet aggregation. Platelet cytoskeleton was analyzed by SDS-PAGE followed by Western immunoblotting with anti-GSH antibody. The main S-glutathionylated cytoskeletal protein proved to be actin, which accounts for 35% of the platelet total protein content. Our results suggest that neither GSSG formation nor a consequent thiol-disulfide exchange mechanism is involved in actin S-glutathionylation of human platelets exposed to diamide. Instead, a mechanism involving the initial oxidative activation of actin thiol groups, which then react with GSH to the protein-GSH mixed disulfides, makes it likely that platelet actin is S-glutathionylated without any significant increase in the GSSG content.