The generation and subsequent fate of glutathionyl radicals in biological systems

Horseradish peroxidase-catalyzed oxidation of p-phenetidine in the presence of either glutathione (GSH), cysteine, or N-acetylcysteine led to the production of the appropriate thioyl radical which could be observed using EPR spectroscopy in conjunction with the spin trap 5,5-dimethyl-1-pyrroline-N-oxide. This confirms earlier work using acetaminophen (Ross, D., Albano, E., Nilsson, U., and Moldéus, P. (1984) Biochem. Biophys. Res. Commun. 125, 109-115). The further reactions of glutathionyl radicals (GS.), generated during horseradish peroxidase-catalyzed oxidation of p-phenetidine and acetaminophen in the presence of GSH, were investigated by following kinetics of oxygen uptake and oxidized glutathione (GSSG) formation. Oxygen uptake and GSSG generation were dependent on the concentration of GSH but above that which was required for maximal interaction with the primary amine or phenoxy radical generated during peroxidatic oxidation of p-phenetidine or acetaminophen, suggesting that a secondary GSH-dependent process was responsible for oxygen uptake and GSSG production. GSSG was the only product of thiol oxidation detected during peroxidatic oxidation of p-phenetidine or acetaminophen in the presence of GSH, but under nitrogen saturation conditions its production was reduced to 8 and 33% of the corresponding amounts obtained under aerobic conditions in the cases of p-phenetidine and acetaminophen, respectively. Nitrogen saturation conditions did not affect horseradish peroxidase-catalyzed metabolism. This shows that the main route of GSSG generation in such reactions is not by dimerization of GS. but via mechanism(s) involving oxygen consumption such as via GSSG-. or via GSOOH.     

Oxidation and nitrosation of thiols at low micromolar exposure to nitric oxide. Evidence for a free radical mechanism

Although the nitric oxide (.NO)-mediated nitrosation of thiol-containing molecules is increasingly recognized as an important post-translational modification in cell signaling and pathology, little is known about the factors that govern this process in vivo. In the present study, we examined the chemical pathways of nitrosothiol (RSNO) production at low micromolar concentrations of .NO. Our results indicate that, in addition to nitrosation by the .NO derivative dinitrogen trioxide (N2O3), RSNOs may be formed via intermediate one-electron oxidation of thiols, possibly mediated by nitrogen dioxide (.NO2), and the subsequent reaction of thiyl radicals with .NO. In vitro, the formation of S-nitrosoglutathione (GSNO) from .NO and excess glutathione (GSH) was accompanied by the formation of glutathione disulfide, which could not be ascribed to the secondary reaction of GSH with GSNO. Superoxide dismutase significantly increased GSNO yields and the thiyl radical trap, 5,5-dimethyl-1-pyrroline N-oxide (DMPO), inhibited by 45 and 98% the formation of GSNO and GSSG, respectively. Maximum nitrosation yields were obtained at an oxygen concentration of 3%, whereas higher oxygen tensions decreased GSNO and increased GSSG formation. When murine fibroblasts were exposed to exogenous .NO, RSNO formation was sensitive to DMPO and oxygen tension in a manner similar to that observed with GSH alone. Our data indicate that RSNO formation is favored at oxygen concentrations that typically occur in tissues. Nitrosothiol formation in vivo depends not only on the availability of .NO and O2 but also on the degree of oxidative stress by affecting the steady-state concentration of thiyl radicals.     

Modulating effect of thiol-disulfide status on [14C]aminopyrine accumulation in the isolated parietal cell

Thiol-oxidizing agents were found to stimulate [14C] aminopyrine accumulation, a reliable index of acid secretory function of isolated canine parietal cells. Glutathione is the predominant intracellular free thiol; thus, its oxidation status largely determines the thiol-disulfide status of the cell by thiol-disulfide interchange reactions. Three agents which alter glutathione oxidation status by different mechanisms were applied to parietal cells in vitro to investigate whether enhanced formation of GSSG alters acid secretory function. The agents studied were diamide (which nonenzymatically oxidizes GSH to GSSG), tert-butyl hydroperoxide (an organic peroxide specifically reduced by glutathione peroxidase, thereby generating GSSG for GSH), and 1,3-bis(2-chloroethyl)-1-nitrosourea (an inhibitor of NADPH:GSSG reductase, which presumably allows the accumulation of GSSG). Each of these agents stimulated aminopyrine accumulation in a dose-dependent fashion. Simple depletion of GSH by diethyl maleate or 2-cyclohexene-1-one did not stimulate aminopyrine accumulation. Likewise, enhanced aminopyrine accumulation occurred at diamide concentrations which did not cause significant depletion of total cellular glutathione. The thiol-reducing agent, dithiothreitol, prevented enhanced aminopyrine accumulation by 1,3-bis(2-chloroethyl)-1-nitrosourea and tert-butyl hydroperoxide. These observations support the hypothesis that thiol-disulfide interchange reactions involving GSSG modulate the acid secretory function of the isolated parietal cell.     

Glutathione-dependent reduction of peroxides during ferryl- and met-myoglobin interconversion: a potential protective mechanism in muscle

Met-myoglobin is oxidized both by H2O2 and other hydroperoxides to a species with a higher iron valency state and the spectral characteristics of ferryl-myoglobin. Glutathione (GSH) reduces the latter species back to met-myoglobin with parallel oxidation to its disulfide (GSSG) but cannot reduce met-myoglobin to ferrous myoglobin. Under aerobic conditions, the GSH-mediated reduction of ferry-myoglobin is associated with O2 consumption and amounts of GSSG are formed far in excess over that of the peroxide added. Under anaerobic conditions, this ratio is close to unity. These results are interpreted in terms of a one-electron redox process involving the reduction of ferryl-myoglobin to met-myoglobin and the one-electron oxidation of GSH to its thiyl radical. Further reactions of thiyl radicals are influenced by the presence of oxygen which will be the determining factor in the ratio H2O2 added/GSSG formed. It is suggested that, when oxygen is limiting, myoglobin may serve as a protector of muscle cells against peroxides and other oxidants.     

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.     

Quinone toxicity in hepatocytes without oxidative stress

The toxicity of quinones is believed to be mediated via redox cycling involving formation of semiquinone radicals which autoxidize to form active oxygen species. However, when the cytotoxicity of benzoquinones was compared using freshly isolated rat hepatocytes, benzoquinones which did not mediate oxidative stress were highly toxic. Thus, the benzoquinone analogs in decreasing order of cytotoxicity were 2-CH3-, 2-Br-, unsubstituted, 2,6-(CH3)2-, 2,5-(CH3)2-, and 2,3,5-(CH3)3-benzoquinone. Cellular thiols were rapidly depleted and glutathione (GSH) was converted to a quinone conjugate without oxidation to glutathione disulfide. No increase in cyanide-resistant respiration was observed and benzoquinone-induced cytotoxicity was not enhanced by inactivation of catalase or glutathione reductase. In contrast, duroquinone [2,3,5,6-(CH3)4-benzoquinone], which stimulated cyanide-resistant respiration and GSH oxidation, was only cytotoxic when catalase or glutathione reductase was inactivated. These results suggest that alkylation and/or oxidative stress may be important mechanisms in the cytotoxicity of benzoquinone derivatives.     

Proteins protect lipid membranes from oxidation by thiyl radicals

Oxidation of polyunsaturated fatty acids by thiyl radicals derived from GSH or Cys is believed to be responsible for some of the biological damage resulting from lipid oxidation under oxidative stress. However, this has not been demonstrated in complex biological systems. In this study, we measured the formation of lipid hydroperoxides in liposomes exposed to radicals generated by gamma radiation from GSH, GSSG, GSMe, Cys and Met. In the absence of proteins, the radicals oxidized the liposome lipids. In the presence of proteins, the thiyl radicals failed to react with the liposomes, even though the protein radicals efficiently oxidized the S-compounds. It appears that the thiyl and other S-radicals were effectively scavenged by the protein before initiating lipid oxidation. The results suggest that membrane lipid oxidation in vivo by thiyl radicals is unlikely to be a significant event.     

Peroxidase-mediated formation of glutathione conjugates from polycyclic aromatic dihydrodiols and insecticides

Using two peroxidative systems (prostaglandin H synthase/arachidonic acid and horseradish peroxidase/H2O2) we observed GSH conjugate formation with a number of compounds including polycyclic aromatic hydrocarbon-diols (PAH-diols), insecticides, and steroids. Several of the conjugates were characterized by chromatography, uv-vis spectrophotometry, and FAB mass spectroscopy. Conjugate formation is dependent upon a functioning peroxidase, GSH, and is markedly enhanced (3- to 10-fold) by the inclusion of a number of reducing cosubstrates including phenol, uric acid, phenylbutazone, and acetaminophen. The mechanism of conjugate formation appears to involve addition of thiyl radical to alkene bonds conjugated to an electron releasing group probably by resonance stabilization of the carbon-centered radical intermediate. Thiyl radicals are formed either directly by GSH reduction of the peroxidase or indirectly by GSH reduction of radicals formed from reducing cosubstrates. The nitrone spin trap, 5,5-dimethyl-1-pyrroline N-oxide, which traps thiyl radicals, totally inhibits production of GSH conjugates in both peroxidative systems. Conjugation of PAH-diols, some of which are penultimate carcinogens, would prevent their metabolism to the diol-epoxides, an ultimate carcinogenic species of PAH. Conjugation by peroxidases appears to be a general pathway for glutathione conjugate formation that may lead to potential detoxification of chemicals.     

Mechanisms of acetaminophen oxidation to N-acetyl-P-benzoquinone imine by horseradish peroxidase and cytochrome P-450

Horseradish peroxidase rapidly catalyzed the H2O2-dependent polymerization of acetaminophen. Acetaminophen polymerization was decreased and formation of GSSG and minor amounts of GSH-acetaminophen conjugates were detected in reaction mixtures containing GSH. These data suggest that horseradish peroxidase catalyzed the 1-electron oxidation of acetaminophen and that GSH decreased polymerization by reducing the product, N-acetyl-p-benzosemiquinone imine, back to acetaminophen. Analyses of reaction mixtures that did not contain GSH showed N-acetyl-p-benzoquinone imine formation shortly after initiation of reactions. When GSH was added to similar reaction mixtures at various times, 3-(glutathion-S-yl)-acetaminophen was formed. The formation and disappearance of this product were very similar to N-acetyl-p-benzoquinone imine formation and were consistent with the disproportionation of 2 mol of N-acetyl-p-benzosemiquinone imine to 1 mol of N-acetyl-p-benzoquinone imine and 1 mol of acetaminophen followed by the rapid reaction of N-acetyl-p-benzoquinone imine with GSH to form 3-(glutathion-S-yl)acetaminophen. When acetaminophen was incubated with NADPH, oxygen and hepatic microsomes from phenobarbital-pretreated rats, 1.2 nmol 3-(glutathion-S-yl)acetaminophen/nmol cytochrome P-450/10 min was formed. Formation of polymers was not observed indicating that N-acetyl-p-benzoquinone imine was formed via an overall 2-electron oxidation rather than a disproportionation reaction. However, when cumene hydroperoxide was replaced by NADPH in microsomal incubations, polymerization was observed suggesting that cytochrome P-450 might also catalyze the 1-electron oxidation of acetaminophen.     

Detection of glutathione thiyl free radical catalyzed by prostaglandin H synthase present in keratinocytes. Study of co-oxidation in a cellular system

We report here the application of the electron spin resonance technique to detect free radicals formed by the hydroperoxidase activity of prostaglandin H synthase in cells. Studies were done using keratinocytes obtained from hairless mice. These cells can be prepared in large number and possess significant prostaglandin H synthase activity. Initial attempts to directly detect free radical metabolites of several amines in cells were unsuccessful. A technique was developed based on the ability of some free radicals formed by prostaglandin hydroperoxidase to oxidize reduced glutathione (GSH) to a thiyl radical, which was trapped by 5,5-dimethyl-1-pyrroline N-oxide (DMPO). Phenol and aminopyrine are excellent hydroperoxidase substrates for this purpose and thus were used for all further experiments. Using this approach we detected the DMPO/GS.thiyl radical adduct catalyzed by cellular prostaglandin hydroperoxidase. The formation of the radical was dependent on the addition of substrate, inhibited by indomethacin, and supported by either exogenous arachidonic acid or endogenous arachidonic acid released from phospholipid stores by Ca2+ ionophore A-23187. The addition of GSH significantly increased the intracellular GSH concentration and concomitantly stimulated the formation of the DMPO/GS.thiyl radical adduct. Phenol, but not aminopyrine, enhanced thiyl radical adduct formation and prostaglandin formation with keratinocytes while both cofactors were equally effective in incubations containing microsomes prepared from keratinocytes. These results suggest that prostaglandin hydroperoxidase-dependent co-oxidation of chemicals can result in the intracellular formation of free radical metabolites.     

Myeloperoxidase catalysed cooxidative metabolism of methimazole: oxidation of glutathione and NADH by free radical intermediates

The myeloperoxidase catalysed oxidation of methimazole in the presence of NADH or GSH resulted in oxygen uptake suggesting that metabolism proceeded via a one electron mechanism. The GSH was oxidised to GSSG and the thiyl radical could be trapped with DMPO while NADH was oxidized to NAD+. Metabolism proceeded without the inactivation of the enzyme myeloperoxidase. Myeloperoxidase catalyzed oxidation of other substrates which proceed via one electron intermediates; 2,6-dimethylphenol, N,N,N',N'-tetramethyl-phenylenediamine and luminol, were all stimulated by methimazole providing further evidence for a methimazole free radical. The presence of iodide stimulated the oxidation of methimazole but inhibited the oxygen uptake in the presence of GSH or NADH suggesting that metabolism in this case proceeded by a two electron mechanism. In contrast, another S-thioureylene drug, thiourea; did not cause oxygen uptake when oxidised in the presence of GSH or NADH indicating that the myeloperoxidase oxidation of thiourea proceeded primarily by a two electron mechanism. The horseradish peroxidase catalysed one electron oxidation of p'p'-biphenol, and 3,3',5,5'-tetramethylbenzidine was reversibly inhibited by methimazole and thiourea by preventing the accumulation of oxidation products via reductive mechanisms whereas the reversible inhibition of guaiacol and luminol oxidation was the result of competitive inhibition. With p,p'-biphenol, and 3,3',5,5'-tetramethylbenzidine unstable adduct formation could be demonstrated.     

The formation of aminopyrine cation radical by the peroxidase activity of prostaglandin H synthase and subsequent reactions of the radical

The oxidation of aminopyrine to an aminopyrine cation radical was investigated using a solubilized microsomal preparation or prostaglandin H synthase purified from ram seminal vesicles. Aminopyrine was oxidized to an aminopyrine cation radical in the presence of arachidonic acid, hydrogen peroxide, t-butyl hydroperoxide or 15-hydroperoxyarachidonic acid. Highly purified prostaglandin H synthase, which processes both cyclo-oxygenase and hydroperoxidase activity, oxidized aminopyrine to the free radical. Purified prostaglandin H synthase reconstituted with Mn2+ protoporphyrin IX, which processes only cyclo-oxygenase activity, did not catalyze the formation of the aminopyrine free radical. Aminopyrine stimulated the reduction of 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid to 15-hydroxy-5,8,11-13-eicosatetraenoic acid. Approximately 1 molecule of 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid was reduced for every 2 molecules of aminopyrine free radical formed, giving a stoichiometry of 1:2. The decay of the aminopyrine radical obeyed second-order kinetics. These results support the proposed mechanism in which aminopyrine is oxidized by prostaglandin H synthase hydroperoxidase to the aminopyrine free radical, which then disproportionates to the iminium cation. The iminium cation is further hydrolyzed to the demethylated amine and formaldehyde. Glutathione reduced the aminopyrine radical to aminopyrine with the concomitant oxidation of GSH to its thiyl radical as detected by ESR of the glutathione thiyl radical adduct.     

Reactions of glutathione and glutathione radicals with benzoquinones.

The reactions of glutathione (GSH) and glutathione radicals with a series of methyl-substituted 1,4-benzoquinones and 1,4-benzoquinone have been studied. It was found that by mixing excess benzoquinone with glutathione at pH above 6.5, the products formed were complex and unstable. All of the other experiments were carried out at pH 6.0, where the main product was stable for several hours. Stopped-flow analysis allowed the measurement of the rates of the rapid reactions between GSH and the quinones, and the products were monitored by High Performance Liquid Chromatography (HPLC). The rates of the reactions vary by five orders of magnitude and must be influenced by steric factors as well as changes in the redox states. It was observed that simple hydroquinones were not formed when the different benzoquinones were mixed with excess GSH and suggests that the initial reaction is addition/reduction rather than electron transfer. In the presence of excess quinone, the hydroquinone of the glutathione conjugate is oxidized back to its quinone. The rates of the reaction were measured. By using the technique of pulse radiolysis, it was possible to measure the reduction of the quinones by GSSG.- and the oxidation of hydroquinones by GS(.). It is proposed that the appearance of GSSG in reactions of quinones with glutathione could be due to oxidation of the hydroquinone by oxygen and the subsequent superoxide or H2O2 promoting the oxidation of GSH to GSSG.     

Cytochrome P-450-mediated oxidation of substrates by electron-transfer; role of oxygen radicals and of 1- and 2-electron oxidation of paracetamol

The mechanism by which the hepatic cytochrome P-450 (Cyt. P-450) containing mixed-function oxidase system oxidizes the analgesic drug paracetamol (PAR) to a hepatotoxic metabolite was studied. Since previous studies excluded the possibility of oxygenation of PAR, three other mechanisms, namely direct 1-electron oxidation by a Cyt. P-450-ferrous-dioxygen complex under concomitant formation of H2O2 to N-acetyl-p-semiquinone imine (NAPSQI), direct 2-electron oxidation by a Cyt. P-450-ferric-oxene complex to N-acetyl-p-benzoquinone imine (NAPQI) and indirect oxidation by active oxygen species released from Cyt. P-450, were considered. Indirect oxidation by active oxygen species was not involved, as active oxygen scavengers such as superoxide dismutase, catalase and DMSO did not affect the oxidation of PAR in hepatic microsomes. No reaction products characteristic for a direct 1-electron oxidation of PAR by Cyt. P-450 were observed: neither NAPSQI radical formation was detectable by ESR, nor PAR-dimer formation, nor stimulation of the microsomal H2O2 production was found to occur. In fact, PAR inhibited the spontaneous microsomal H2O2 formation. Studies on the reactions of NAPSQI with glutathione (GSH) revealed that NAPSQI hardly conjugated with GSH to a 3-glutathionyl-paracetamol conjugate (PAR-GSH) conjugate. The reactions of the elusive reactive metabolite formed during microsomal oxidation of PAR in the presence of GSH closely resembled those of synthetic NAPQI: both PAR-GSH and oxidized glutathione (GSSG) formation occurred. Furthermore, in agreement with a 2-electron oxidation hypothesis, iodosobenzene-dependent oxidation of PAR by cyt. P-450 in the presence of GSH resulted in the formation of the PAR-GSH conjugate. It is concluded that bioactivation of PAR by the Cyt. P-450 containing mixed-function oxidase system consists of a direct 2-electron oxidation to NAPQI.     

The roles of thiol-derived radicals in the use of 2',7'-dichlorodihydrofluorescein as a probe for oxidative stress

2',7'-Dichlorodihydrofluorescein (DCFH2) is one of the most widely used probes for detecting intracellular oxidative stress, but requires a catalyst to be oxidized by hydrogen peroxide or superoxide and reacts nonspecifically with oxidizing radicals. Thiyl radicals are produced when many radicals are "repaired" by thiols, but are oxidizing agents and thus potentially capable of oxidizing DCFH2. The aim of this study was to investigate the reactivity of thiol-derived radicals toward DCFH2 and its oxidized, fluorescent form 2',7'-dichlorofluorescein (DCF). Thiyl radicals derived from oxidation of glutathione (GSH) or cysteine (CysSH) oxidized DCFH2 with rate constants at pH 7.4 of approximately 4 or approximately 2x10(7) M(-1) s(-1), respectively. Both the rates of oxidation and the yields of DCF were pH-dependent. Glutathione-derived radicals interacted with DCF, resulting in the formation of DCFH* absorbing at 390 nm and loss of fluorescence; in contrast, cysteine-derived radicals did not cause any depletion of DCF fluorescence. We postulate that the observed apparent difference in reactivity between GS* and CysS* toward DCF is related to the formation of carbon-centered, reducing radicals from base-catalyzed isomerization of GS*. DCF formation from interaction of DCFH2 with GS* was inhibited by oxygen in a concentration-dependent manner over the physiological range. These data indicate that in applying DCFH2 to measure oxidizing radicals in biological systems, we have to consider not only the initial competition between thiols and DCFH2 for the oxidizing radicals, but also subsequent reactions of thiol-derived radicals, together with variables--including pH and oxygen concentration--which control thiyl radical chemistry.     

Evidence for free radical formation during horseradish peroxidase-catalyzed N-demethylation of crystal violet.

Crystal violet (gentian violet) can undergo an oxidative metabolism, catalyzed by horseradish peroxidase, resulting in formaldehyde formation. The N-demethylation reaction was strongly inhibited by reduced glutathione. Evidence for the formation of a crystal violet radical during the horseradish peroxidase catalyzed reaction was the detection of thiyl and ascorbate radicals from glutathione and ascorbate, respectively. The concentration of radicals from both compounds was significantly increased in the presence of crystal violet. Oxygen uptake was stimulated when glutathione was present in the system and this oxygen uptake was dependent on the dye and enzyme concentration. Oxygen uptake did not occur when ascorbate, instead of glutathione, was present in the system. However, when glutathione was present, ascorbate totally inhibited the glutathione-stimulated oxygen uptake in the crystal violet/horseradish peroxidase/hydrogen peroxide system. Although a weak ESR spectrum from a crystal violet-derived free radical was detected when the dye reacted with H2O2 and horseradish peroxidase, using the fast flow technique, this spectrum could not be interpreted.     

Mechanism of sulfite cytotoxicity in isolated rat hepatocytes

Sulfite (SO(3)(2-)) has been widely used as preservative and antimicrobial in preventing browning of foods and beverages. SO(2), a common air pollutant, also is capable of producing sulfite and bisulfite depending on the pH of solutions. A molybdenum-dependent mitochondrial enzyme, sulfite oxidase, oxidizes sulfite to inorganic sulfate and prevents its toxic effects. In the present study, sulfite toxicity towards isolated rat hepatocytes was markedly increased by partial inhibition of cytochrome a/a(3) by cyanide or by putting rats on a high-tungsten/low-molybdenum diet, which result in inactivation of sulfite oxidase. Sulfite cytotoxicity was accompanied by a rapid disappearance of GSSG followed by a slow depletion of reduced glutathione (GSH). Depleting hepatocyte GSH beforehand increased cytotoxicity of sulfite. On the other hand, dithiothreitol (DTT), a thiol reductant, added even 1h after the addition of sulfite to hepatocytes, prevented cell death and restored hepatocyte GSH levels. Sulfite cytotoxicity was also accompanied by an increase of oxygen uptake, reactive oxygen species (ROS) formation and lipid peroxidation. Cytochrome P450 inhibitors, metyrapone and piperonyl butoxide also prevented sulfite-induced cytotoxicity and lipid peroxidation. Desferroxamine and antioxidants also protected the cells against sulfite toxicity. These findings suggest that cytotoxicity of sulfite is mediated by free radicals as ROS formation increases by sulfite and antioxidants prevent its toxicity. Reaction of sulfite or its free radical metabolite with disulfide bonds of GSSG and GSH results in the compromise of GSH/GSSG antioxidant system leaving the cell susceptible to oxidative stress. Restoring GSH content of the cell or protein-SH groups by DTT can prevent sulfite cytotoxicity.     

The formation of styrene glutathione adducts catalyzed by prostaglandin H synthase. A possible new mechanism for the formation of glutathione conjugates

The metabolism of styrene by prostaglandin hydroperoxidase and horseradish peroxidase was examined. Ram seminal vesicle microsomes in the presence of arachidonic acid or hydrogen peroxide and glutathione converted styrene to glutathione adducts. Neither styrene 7,8-oxide nor styrene glycol was detected as a product in the incubation. Also, the addition of styrene 7,8-oxide and glutathione to ram seminal vesicle microsomes did not yield styrene glutathione adducts. The peroxidase-generated styrene glutathione adducts were isolated by high pressure liquid chromatography and characterized by NMR and tandem mass spectrometry as a mixture of (2R)- and (2S)-S-(2-phenyl-2-hydroxyethyl)glutathione. (1R)- and (1S)-S-(1-phenyl-2-hydroxyethyl)glutathione were not formed by the peroxidase system. The addition of phenol or aminopyrine to incubations, which greatly enhances the oxidation of glutathione to a thiyl radical by peroxidases, increased the formation of styrene glutathione adducts. We propose a new mechanism for the formation of glutathione adducts that is independent of epoxide formation but dependent on the initial oxidation of glutathione to a thiyl radical by the peroxidase, and the subsequent reaction of the thiyl radical with a suitable substrate, such as styrene.     

Hypochlorite-induced oxidation of thiols: Formation of thiyl radicals and the role of sulfenyl chlorides as intermediates

Activated phagocytic cells generate hypochlorite (HOCl) via release of hydrogen peroxide and the enzyme myeloperoxidase. HOCl plays an important role in bacterial cell killing, but excessive or misplaced production of HOCl is also known to cause tissue damage. Studies have shown that low-molecular-weight thiols such as reduced glutathione (GSH), and sulfur-containing amino acids in proteins, are major targets for HOCl. Radicals have not generally been implicated as intermediates in thiol oxidation by HOCl, though there is considerable literature evidence for the involvement of radicals in the metal ion-, thermal- or UV light-catalysed decomposition of sulfenyl or sulfonyl chlorides which are postulated intermediates in thiol oxidation. In this study we show that thiyl radicals are generated on reaction of a number of low-molecular-weight thiols with HOCl. With sub-stoichiometric amounts of HOCl, relative to the thiol, thiyl radicals are the major species detected by EPR spin trapping. When the HOCl is present in excess over the thiol, additional radicals are detected with compounds which contain amine functions; these additional radicals are assigned to nitrogen-centered species. Evidence is presented for the involvement of sulfenyl chlorides (RSCl) in the formation of these radicals, and studies with an authentic sulfenyl chloride have demonstrated that this compound readily decomposes in thermal-, metal-ion- or light-catalysed reactions to give thiyl radicals. The formation of thiyl radicals on oxidation of thiols with HOCl appears to compete with non-radical reactions. The circumstances under which radical formation may be important are discussed.     

Antioxidant and pro-oxidant effect of the thiolic compounds N-acetyl-L-cysteine and glutathione against free radical-induced lipid peroxidation

The antioxidant ability of thiol compounds has been the subject of much of the current research about oxidative stress. The direct scavenging of hydroxyl radicals by thiols has been suggested as their protection mechanisms. Nevertheless, the interaction of thiols with reactive radicals can generate thiyl radicals, which, in turn, may impart a pro-oxidant function. The purpose of this study has been to establish the effect of the thiol compounds N -acetyl- l -cysteine (NAC) and glutathione (GSH) against the peroxidative processes involving membrane lipids. The results obtained support the ability of NAC and GSH to suppress the 2,2'-azobis-(2-amidinopropane) dihydrochloride (AAPH)-dependent or to enhance the Fe 2+ /H 2 O 2 -dependent oxidative actions. The evaluation of thiobarbituric acid reactive substances (TBARS) production, the study of the influence of oxidants on membrane fluidity and the measurements of the changes in the fluorescence of bilayer probes, such as 3-( p -(6-phenyl)-1,3,5-hexatrienyl)phenylpropionic acid (DPH-PA), have shown the antioxidant and pro-oxidant effects of both NAC and GSH. Also their dependence on the nature of the radicals generated by the oxidative systems used has been shown. The use of ESR spectroscopy has allowed us to establish the ability of these compounds to scavenge the AAPH-derived radicals, to determine the formation of thiyl radicals in the iron-mediated oxidation and to evaluate the enhanced production of hydroxyl radicals by NAC and GSH.