Depletion Of Intracellular GSH Research Articles

Aged garlic extract attenuates intracellular oxidative stress.

Oxidation of low density lipoprotein (LDL) has been recognized as playing an important role in the initiation and progression of atherosclerosis. We recently reported that aged garlic extract (AGE) inhibited LDL oxidation and minimized oxidized LDL-induced cell injury. In this study, the antioxidant effects of AGE were further examined using bovine pulmonary artery endothelial cells (PAEC) and murine macrophages. Lactate dehydrogenase (LDH) release, as an index of membrane injury, and intracellular glutathione (GSH) levels were determined. Oxidized LDL (Ox-LDL) caused an increase of LDH release and depletion of GSH. Pretreatment with AGE prevented these changes. AGE exhibited an inhibition of Ox-LDL-induced peroxides in PAEC. AGE suppressed peroxides in murine Macrophage (J774 cells) dose-dependently. The J774 cells were also incubated with AGE, interferon-gamma (IFN-gamma) and lipopolysaccharide (LPS) and nitric oxide (NO) production was measured. AGE inhibited NO production in J774 cells. In a cell free system, AGE was shown to scavenge H2O2 dose-dependently. Our data demonstrate that AGE can protect the endothelial cells from oxidized LDL-induced injury by preventing depletion of intracellular GSH and by removing peroxides. AGE also reduces levels of NO and peroxides in macrophages. These data suggest that AGE is a useful protective agent against cytotoxicity associated with Ox-LDL and NO, and it may thus be useful for the prevention of atherosclerosis and cardiovascular diseases.

Effect of intracellular glutathione on the production of prostaglandin D2 in RBL-2H3 cells oxidized by tert-butyl hydroperoxide.

The liberation of arachidonic acid and the production of prostaglandin D2 (PGD2) were significantly influenced by peroxide and the level of intracellular glutathione (GSH). The productions of free arachidonic acid and PGD2 in RBL-2H3 cells were enhanced considerably by exposure to tert-butyl hydroperoxide (t-BHP). The liberation of arachidonic acid induced by t-BHP was not inhibited by EGTA. The productions of PGD2 and arachidonic acid induced by t-BHP were significantly facilitated by the depletion of intracellular GSH using buthionine sulfoximine (BSO) or diethyl maleate (DEM), although the depletion of GSH had no effect on the production of PGD2 induced by A23187. t-BHP failed to activate the conversion of free arachidonic acid to PGD2, since the formation of PGD2 from exogenously added arachidonic acid was not enhanced by treatment with t-BHP. The level of lipid hydroperoxides in t-BHP-treated cells was significantly elevated by treatment with DEM. These results suggest that hydroperoxides increase the free arachidonic acid available for the synthesis of PGD2 by activating phospholipase A2 (PLA2) and that the depletion of GSH by DEM accelerates the activation of PLA2 by raising peroxide levels in cells. Thus, the observed alterations in GSH levels are large enough to cause increased PGD2 synthesis in RBL-2H3 cells exposed to oxidative stress.

S-Allylcysteine Attenuates Oxidative Stress in Endothelial Cells

Oxidation of low-density lipoprotein (LDL) has been recognized as playing an important role in the initiation and progression of atherosclerosis. We recently reported that S-allylcysteine (SAC), one of the major compounds in the aged garlic extract (AGE), inhibited LDL oxidation and minimized oxidized LDL–induced cell injury. In this study, the antioxidant effects of SAC were further determined using several in vitro assay systems. Pulmonary artery endothelial cells (PAECs) were preincubated with SAC at 37°C and 5% CO2 for 24 hr, washed, and then exposed to 0.1 mg/ml oxidized LDL for 24 hr. Lactate dehydrogenase (LDH) release, as an index of membrane injury, and intracellular glutathione (GSH) levels were determined. Oxidized LDL caused an increase of LDH release and depletion of GSH. Pretreatment with SAC prevented these changes. Peroxides were measured directly in 24-well plates using a fluorometric assay. SAC dose-dependently inhibited oxidized LDL-induced release of peroxides in PAEC. In a cell-free system, SAC was shown to scavenge hydrogen peroxide. Our data demonstrate that SAC can protect endothelial cells from oxidized LDL-induced injury by removing peroxides and preventing the intracellular GSH depletion and suggest that this compound may be useful for the prevention of atherosclerosis.

Glutathione is present in reproductive tract secretions and improves development of mouse embryos after chemically induced glutathione depletion.

We investigated the hypothesis that reduced glutathione (GSH) is present in secretions of the female reproductive tract and that this extracellular GSH may protect preimplantation mouse embryos after intracellular GSH depletion. The cleavage-stage mouse embryo cannot synthesize GSH de novo and is unable to recover from glutathione depletion in vitro. Analysis of GSH and total protein of oviduct flushings, quantified by HPLC and the Bradford method, respectively, revealed 51 nmol GSH per mg total protein. Embryos were treated with 60 microM diethyl maleate (DEM) to deplete cellular GSH. When cultured with 1 mM GSH, these embryos exhibited improved development compared to those cultured in control medium (96% vs. 87% morula [p < 0.05], 78% vs. 75% blastocyst, 58% vs. 54% expanded blastocyst, 21% vs. 17% initiating hatching blastocyst). However, intracellular GSH content of embryos was not significantly increased by the culture of DEM-treated embryos in medium containing GSH for 16, 40, or 64 h of incubation, suggesting that the embryo is not capable of taking up intact GSH. Furthermore, addition of buthionine sulfoximine (which inhibits synthesis of GSH) or acivicin (which inhibits breakdown of GSH at the membrane) to culture medium blocked the improvement in development. These data suggest that GSH in reproductive tract fluid may help protect preimplantation embryos from the adverse effects of toxicant-induced and endogenous depletion of embryonic GSH.

The relative importance of oxidative stress versus arylation in the mechanism of quinone-induced cytotoxicity to platelets

Our previous studies demonstrated that menadione is cytotoxic to rat platelets. In an attempt to assess the relative contributions of enzymatic redox cycling versus arylation in menadione-induced cytotoxicity, we have studied three quinones with different mechanisms of action: 2,3-dimethoxy-1,4-naphthoquinone (DMNQ; pure redox cycler), menadione (both redox cycler and arylator), and 1,4-benzoquinone (BQ; pure arylator). BQ was more toxic to rat platelets than menadione, while DMNQ did not cause LDH leakage at all. Cellular uptake kinetics revealed that DMNQ concentration taken up by the cells was equivalent to that decreased in incubation medium. On the other hand, the concentrations of BQ and menadione taken into the cells were significantly lower than the decreases in concentrations seen in the incubation medium. This suggests indirectly that BQ and menadione may have undergone arylation, binding to glutathione (GSH) or protein thiols. The difference in arylation capacity between BQ and menadione was well correlated with their relative cytotoxicity (LDH leakage) observed in platelets. All three quinones caused a rapid, extensive depletion of intracellular GSH in platelets. Treatments with BQ and menadione did not result in formation of oxidized glutathione (GSSG), whereas DMNQ showed a time-dependent increase in GSSG. Altogether, these results suggest that enzymatic redox cycling does not play a critical role in quinone-induced cytotoxicity in rat platelets, while arylation is likely to be quinone’s primary mechanism of action.

L- S, R-buthionine sulfoximine: historical development and clinical issues

l- S, R-buthionine sulfoximine ( l- S, R BSO) is a potent specific inhibitor of γ-glutamylcysteine synthetase, the rate-limiting step in glutathione (GSH) biosynthesis. GSH is an important component of tumor drug resistance based on a strong association and recent transfection studies. Depletion of intracellular GSH by BSO significantly enhances the cytotoxicity of many cytotoxic agents, principally alkylating agents and platinating compounds but also irradiation and anthracyclines. Phase I clinical trials of BSO+melphalan ( l-PAM)have been carried out and observed little toxicity with BSO alone and increased myelosuppression with BSO+ l-PAM. Consistent and profound (<10% of control) GSH depletion was observed in serial determinations of tumor GSH levels in patients receiving continuous infusion (CI) BSO. Evidence of clinical activity has been observed in patients with alkylating or platinating agent-refractory tumors. Phase II evaluation of CI BSO with l-PAM is in progress.

Cytotoxicity of a series of mono- and di-substituted thiourea in freshly isolated rat hepatocytes: a preliminary structure-toxicity relationship study

The cytotoxicity of a series of 12 mono- and 4 di-substituted thiourea containing compounds in freshly isolated rat hepatocytes was investigated. It was found that thiourea toxicity, as evidenced by an increase in LDH-leakage from the cells, was accompanied by a depletion of intracellular glutathione (GSH). No increase in lipid peroxidation was observed with any of the thiourea. Burimamide and thioperamide, thiourea-containing histamine receptor ligands, were also found to deplete intracellular GSH. A clear structure-toxicity relationship was uncovered among a homologous series of N-phenylalkylthiourea. N-benzylthiourea (BTU) and N-phenylethylthiourea (PETU) were found to be non-toxic at a concentration of 1 mM, while N-phenylpropylthiourea (PPTU) and N-phenylbutylthiourea (PBTU) were found to cause significant LDH-leakage from the cells, accompanied by a depletion of intracellular GSH. This structure-toxicity relationship was further investigated using hepatocytes of differentially induced rats, however, no significantly different results were obtained when using hepatocytes of rats induced with phenobarbital (PB) or β-naphthoflavone (BNF). Oxidation of the thiourea moiety is thought to be the first step in the bioactivation of thiourea containing compounds. The oxidation of thiocholine sulfenic acids, produced by FMO-mediated oxidation of the thiourea moiety, was used to determine whether the compounds examined are substrates for the FMO enzymes in rat liver. No clear relationship was found between cytotoxicity of the mono-substituted thiourea and lipophilicity of the N-substituent, nor with the FMO-mediated oxidation of the thionosulfur atom of the mono-substituted thiourea. It is concluded from this study, that thiourea toxicity in rat hepatocytes is structure-dependent and manifests itself as LDH-leakage and as a depletion of intracellular non-protein sulfhydryls, notably GSH, most likely followed by alkylation of vital macromolecular structures.

Tetravinyl-tetramethylcyclo-tetrasiloxane (tetravinyl D4) is a mutagen in Rat2lambda lacI fibroblasts.

Small fragments of silicone gels injected intraperitoneally have been used to induce plasmacytomas in genetically susceptible mice. Silicone oils, in contrast to silicone gels, are apparently not tumorigenic in the mouse plasmacytoma system. The reason for this difference as well as the mechanism of silicone gel-induced plasmacytoma development is poorly understood. We chose to examine the possibility that low molecular wt silicone compounds such as siloxanes, leaking from the complex silicone gel matrix into the surrounding tissue, may be mutagenic. We postulate that this mutagenicity may be a critical determinant of the plasmacytoma inducing potency of silicone gels. Six siloxane compounds, either linear or cyclic di-, tri-, or tetrasiloxanes substituted with methyl or vinyl moieties, were selected as model compounds to study mutagenicity in Rat2lambda lacI fibroblasts in vitro. Using phage lambda-derived lacI/lacZ genes as target/reporter genes to quantitate mutagenesis, and gamma-cyclodextrin as vehicle to effectively deliver siloxanes, we found that exposure to 50 microM of tetravinyl-tetramethylcyclo-tetrasiloxane (tetravinyl D4) resulted in a modest 1.7-fold increase of mutant frequencies over controls in Rat2lambda lacI cells. In related toxicity experiments, tetravinyl D4 was shown to perturb lipid membranes leading to a loss of cytosolic glutathione (GSH), which by itself resulted in a 1.5-fold increased mutant rate in Rat2lambda lacI cells. We conclude that certain siloxanes may act as direct mutagens in mammalian cells. In addition, siloxane-induced mutagenicity may be enhanced by the depletion of intracellular GSH caused by the interaction of lipophilic siloxanes with cell membranes.

Cytotoxicity of paraquat in freshly isolated rat hepatocytes: effects of L-carnitine.

The effects of L-carnitine, a mitochondrial carrier of fatty acids, on paraquat (PQ) cytotoxicity in freshly isolated rat hepatocytes were studied. Addition of PQ (10 mM) to hepatocytes resulted in a time-dependent depletion of intracellular glutathione (GSH) accompanied by an increase in accumulation of malondialdehyde (MDA) in the incubation medium which proceeded to a loss of cell viability. Pretreatment of hepatocytes with L-carnitine (50-mM) alone did not affect cell viability or intracellular levels of GSH, or accumulation of MDA in the medium during the incubation period; however, pretreatment with L-carnitine 30 min prior to PQ addition did promote the depletion of intracellular GSH and MDA accumulation induced by PQ, and ultimately enhanced the cytotoxicity of PQ.

Free radical activity of industrial fibers: role of iron in oxidative stress and activation of transcription factors.

We studied asbestos, vitreous fiber (MMVF10), and refractory ceramic fiber (RCF1) from the Thermal Insulation Manufacturers' Association fiber repository regarding the following: free radical damage to plasmid DNA, iron release, ability to deplete glutathione (GSH), and activate redox-sensitive transcription factors in macrophages. Asbestos had much more free radical activity than any of the man-made vitreous fibers. More Fe3+ was released than Fe2+ and more of both was released at pH 4.5 than at pH 7.2. Release of iron from the different fibers was generally not a good correlate of ability to cause free radical injury to the plasmid DNA. All fiber types caused some degree of oxidative stress, as revealed by depletion of intracellular GSH. Amosite asbestos upregulated nuclear binding of activator protein 1 transcription factor to a greater level than MMVF10 and RCF1; long-fiber amosite was the only fiber to enhance activation of the transcription factor nuclear factor kappa B (NF kappa B). The use of cysteine methyl ester and buthionine sulfoximine to modulate GSH suggested that GSH homeostasis was important in leading to activation of transcription factors. We conclude that the intrinsic free radical activity is the major determinant of transcription factor activation and therefore gene expression in alveolar macrophages. Although this was not related to iron release or ability to deplete macrophage GSH at 4 hr, GSH does play a role in activation of NF kappa B.

Efflux of reduced glutathione after exposure of human lung epithelial cells to crocidolite asbestos.

This study investigated glutathione (GSH) homeostasis in human lung epithelial cells (A549) exposed to crocidolite. Exposure of A549 cells to 3 micrograms/cm2 crocidolite resulted in a decrease in intracellular reduced glutathione by 36% without a corresponding increase in GSH disulfide. After a 24-hr exposure to crocidolite, 75% of the intracellular GSH lost was recovered in the extracellular medium, of which 50% was in reduced form. Since the half-life of reduced GSH in culture medium was less than 1 hr, this suggests that reduced GSH was released continuously from the cells after treatment. The release of GSH did not appear to result from nonspecific membrane damage, as there was no concomitant release of lactate dehydrogenase or 14C-adenine from loaded cells after crocidolite treatment for 24 hr. Crocidolite exposure resulted in the formation of S-nitrosothiols but no increase in the level of GSH-protein mixed disulfides or GSH conjugates. Exposure of A549 cells to crocidolite for 24 hr decreased gamma glutamylcysteine synthetase (gamma-GCS) activity by 47% without changes in the activities of GSH reductase, GSH peroxidase, GSH S-transferase, or glucose-6-phosphate dehydrogenase. Treatment of cells with crocidolite pretreated with the iron chelator desferrioxamine B resulted in the same level of intracellular GSH depletion and efflux and the same decrease in gamma-GCS activity as treatment with unmodified crocidolite, which suggests that iron-catalyzed reactions were not responsible for the GSH depletion.

Role of cellular thiol status in tocopheryl hemisuccinate cytoprotection against ethyl methanesulfonate-induced toxicity

Suspensions of rat hepatocytes treated with the alkylating agent ethyl methanesulfonate (EMS) exhibited extensive lipid peroxidation as well as rapid and near complete depletion of cellular reduced glutathione (GSH) levels prior to cell death. Pretreatment of hepatocytes with medium deficient in sulfur amino acids accelerated cell death induced by EMS, confirming the previously reported cytoprotective role for GSH in this toxic event. Nearly all of the cellular GSH lost following 50 mM EMS treatment was accounted for as S-ethyl glutathione (GS-Et). No significant formation of glutathione disulfide was observed. The GS-Et formed was not exported from the cell but remained at high intracellular concentrations throughout the course of the experiment. In addition, EMS treatment inhibited the efflux of intracellular GSH and inhibited the cellular accumulation of glutamate (Glu). Supplementation of hepatocytes with 25 μM d- α-tocopheryl hemisuccinate (TS) protected these cells against EMS-induced lipid peroxidation and cell death. Cytoprotection with TS had no effect on EMS-induced depletion of intracellular GSH or intracellular levels of GS-Et or Glu. However, TS supplementation did prevent EMS-induced depletion of cellular protein thiols. Interestingly, the pretreatment of hepatocytes with 1 mM dithiothreitol promoted EMS toxicity. The results of this study suggest that the cytoprotective abilities of TS are related to the prevention of both EMS-induced lipid peroxidation and protein thiol depletion. Thus, the onset of lipid peroxidation and the loss of protein thiols in hepatocytes appear to be critical cellular events leading to EMS-induced cell death.

Conjugation of glutathione with the reactive metabolites of 1, 1-dichloroethylene in murine lung and liver.

Exposure to 1,1-dichloroethylene (DCE) elicits lung and liver cytotoxicities that are manifested in bronchiolar Clara cell injury and centrilobular necrosis, respectively. The tissue damage is associated with cytochrome P450-dependent bioactivation of DCE to reactive intermediates, and is consistent with the finding that the target cells coincided with the sites of high concentrations of cytochrome P450 enzymes. The metabolites formed from DCE bind covalently to cellular macromolecules, and the extent of binding and cell damage are inversely related to the content of intracellular glutathione (GSH). Histochemical studies showed that staining for GSH in the lung is localized in the bronchiolar epithelial and alveolar septal cells, with relatively strong staining in the Clara cells. In the liver, staining is observed rather uniformly in hepatocytes distributed across the hepatic lobule. Depletion of GSH correlates with the Clara cell damage and centrilobular necrosis observed in the lung and liver, respectively. The primary metabolites of DCE formed in lung and liver microsomal incubations have been identified as DCE-epoxide, 2,2-dichloroacetaldehyde and 2-chloroacetyl chloride. All are electrophilic metabolites that form secondary reactions including conjugation with GSH. Results of our studies indicated that the DCE-epoxide is the major metabolite forming conjugates with GSH, and this reaction is likely responsible for the depletion of GSH observed in vivo. Our findings support the premise that, following depletion of intracellular GSH, metabolites of DCE including the DCE-epoxide bind to cellular proteins, a process which leads to cell damage and suggests that conjugation with the thiol nucleophile represents a-detoxification mechanism.

C-myc-Dependent hepatoma cell apoptosis results from oxidative stress and not a deficiency of growth factors.

Expression of c-myc regulates apoptotic cell death in the human hepatoma cell line HuH-7 during culture in serum-free medium (SFM) plus zinc. To understand the mechanism of this c-myc effect, the ability of various serum-contained factors to prevent apoptosis was determined. Apoptosis was not inhibited by growth factors and was even accelerated by supplementation with insulin-like growth factor I or insulin. Cell death was prevented by SFM supplementation with the amino acid glutamine but not serine or asparagine. Improved cell survival with glutamine was associated with increased levels of glutathione (GSH). In HuH-7 cells cultured in SFM plus zinc, c-myc expression led to decreased levels of GSH, and elevated intracellular levels of hydrogen peroxide (H2O2). Cell death induced by c-myc expression was inhibited by the addition of catalase or dimethyl sulfoxide, a hydroxyl radical scavenger, or by increased intracellular expression of catalase. In contrast to findings in fibroblasts, c-myc-dependent apoptosis during serum deprivation in HuH-7 hepatoma cells was unrelated to a loss of growth factors. Apoptosis resulted from H2O2-mediated oxidative stress with associated glutamine dependent intracellular GSH depletion.

Modified hemoglobin solution, with desired pharmacological properties, does not activate nuclear transcription factor NF-kappa B in human vascular endothelial cells.

The aim of the present study was to evaluate the role of hemoglobin (Hb) and the contribution of chemically modified Hb solutions on the activation of nuclear transcription factor. NF-kappa B, and propagation of oxidative stress within human vascular endothelial cells. The activation of an oxidative stress-sensitive NF-kappa B can be linked with the propagation of an inflammatory state via rapid induction of genes for several pro-inflammatory mediators. Human coronary artery endothelial cells (HCAEC) were cultured on glass coverslips or cell culture plates to confluence. Then, the cells were incubated for up to 18 hours with endothelial basal medium (EBM) supplemented with 5% FBS and test agents in a concentration of 0.1 and 0.2 mmol: 1) unmodified bovine Hb (UHb): 2) modified Hb solution polymerized with glutaraldehyde (GLUT-Hb), and 3) a novel modified Hb solution (Hb-PP-GSH) prepared according to our patented procedure (U.S. Patent No. 5,439,882). The positive control for the NF-kappa B activation study included a treatment of the cells with: I) endotoxin: IL-1; TNF; and H2O2. Results indicate that Hb's pro-oxidant potential was influenced by the type of chemical modification procedure. The GLUT-Hb autoxidation rate, peroxidase-like activity and reactivity with H2O2/ferryl species formation were higher as compared to UHb, by 15%, 35% and 30%, respectively. However, pro-oxidant potential of Hb-PP-GSH was significantly lower than that of UHb (by 22%, 12% and 28%, respectively). The extent of oxidative stress of the HCAECs was found to be the Hb modification-type and concentration dependent. Although the highest endothelial lipid peroxidation and the largest depletion of intracellular GSH was associated with 0.2 mmol of GLUT-Hb, the Hb-PP-GSH did not produce significant changes when compared to the control cells. The UHb generated a moderate oxidative stress to the endothelium. The immunofluorescent and EMSA results indicate a correlation between the type of Hb chemical modification and the induction of NF-kappa B nuclear translocation. We found that GLUT-Hb rapidly activated NF-kappa B and induced nuclear translocation. Treatment of the cells with an increasing amount of UHb leads to the partial nuclear induction of NF-kappa B. However, Hb-PP-GSH did not activate NF-kappa B directly. In this study, the positive control cells treated with endotoxin, IL-1 or TNF demonstrated full nuclear translocations, whereas H2O2 caused only partial induction. In conclusion, nuclear translocation of NF-kappa B by Hb solutions might be dependent on Hb's pro-oxidant potential and extent of Hb-mediated endothelial oxidative stress. Besides the low oxidative potential of Hb-PP-GSH, the observed lack of NF-kappa B activation by this Hb solution can be also related to the anti-inflammatory properties of adenosine which is used in our novel modification procedure. In this study, only the Hb-PP-GSH, cross-linked intramolecularly with o-adenosine triphosphate and intermolecularly with o-adenosine, and combined with reduced glutathiore, was shown to be non-toxic to the endothelium and promises to be an effective free-Hb based blood substitute.

Modulating Role of Endogenous Reduced Glutathione in Tert-Butyl Hydroperoxide-Induced Cell Injury in Isolated Rat Hepatocytes

The role of endogenous reduced glutathione (GSH) in tert-butyl hydroperoxide (TBHP)-induced cell injury was examined in isolated rat hepatocytes. When liver cell injury was estimated from release of transaminases from hepatocytes into the incubation medium, cell injury in hepatocytes (2 × 10 6 cells/ml) incubated in Hanks' balanced salt solution (pH 7.2) containing 1.0 mM TBHP at 37°C was potentiated with enhanced lipid peroxidation by prior depletion of intracellular GSH which was induced by diethylmaleate, a GSH depletor. GSH-depleted hepatocytes were incubated with γ-glutamylcysteinylethyl ester ( γ-ECOEt), which is known to be converted to GSH via glutathione synthetase after its hydrolysis by esterase, at concentrations of 1.0 to 10 mM in order to replenish intracellular GSH. Although TBHP-induced cell injury and lipid peroxidation were enhanced in GSH-depleted hepatocytes, these enhancements were prevented with the consumption of intracellular GSH in GSH-depleted hepatocytes pretreated with 5.0 mM γ-ECOEt. These preventive effects were observed at any time point during the TBHP treatment over a 60 min period and depended on the concentration of γ-ECOEt used. But, no preventive effect was found in GSH-depleted hepatocytes pretreated with 5.0 mM GSH. No prevention of the potentiation of TBHP-induced cell injury found in GSH-depleted hepatocytes occurred in GSH-depleted hepatocytes pretreated with both 5.0 mM γ-ECOEt and 250 μM bis-( p-nitrophenyl)phosphate, a nonspecific esterase inhibitor. γ-ECOEt treatment caused an increase in intracellular GSH content in GSH-depleted hepatocytes, while treatments of both γ-ECOEt and the esterase inhibitor caused no increase in intracellular GSH content in the cells. These results indicate that endogenous GSH modulates TBHP-induced cell injury and lipid peroxidation in isolated rat hepatocytes. The present results suggest that endogenous GSH should play a critical role in TBHP-induced cell injury in isolated rat hepatocytes and that in rat hepatocytes treated with TBHP, enhanced lipid peroxidation with the consumption of intracellular GSH could be associated with the initiation of cell injury.

Hydrogen peroxide inhibits gap junctional intercellular communication in glutathione sufficient but not glutathione deficient cells.

Cell to cell communication via gap junctions is essential in the maintenance of the homeostatic balance of multicellular organisms. Aberrant intercellular gap junctional communication (GJIC) has been implicated in tumor promotion, neuropathy and teratogenesis. Oxidative stress has also been implicated in similar pathologies such as cancer. We report a potential link between oxidative stress and GJIC. Hydrogen peroxide, a known tumor promoter, inhibited GJIC in WB-F344 rat liver epithelial cells with an I50 value of 200 microM. Inhibition of GJIC by H2O2 was reversible as indicated by the complete recovery of GJIC with the removal of H2O2 via a change of fresh media. Free radical scavengers, such as t-butyl alcohol, propylgallate, and Trolox, did not prevent the inhibition of GJIC by H2O2, which indicated that the effects of H2O2 on GJIC was probably not a consequence of aqueous free radical damage. The depletion of intracellular GSH reversed the inhibitory effect of H2O2 on GJIC. The treatment of glutathione-sufficient cells with H2O2 resulted in the hyperphosphorylation of connexin43, which is the basic subunit of the hexameric gap junction protein, as determined by Western blot analysis. TPA, a well-known tumor promoter, also inhibits GJIC via hyperphosphorylation of GJIC, which is a result of protein kinase-C activation. However, H2O2 also induced hyperphosphorylation in GSH-deficient cells that had normal rates of GJIC. Therefore, the mechanism of GJIC inhibition must be different from the TPA-pathway and involves GSH.

Methylmercury Efflux from Brain Capillary Endothelial Cells Is Modulated by Intracellular Glutathione but Not ATP

To reach its target tissue, methylmercury must traverse brain capillary endothelial cells, the site of the blood–brain barrier. Methylmercury uptake from blood plasma into these cells is mediated in part by an amino acid carrier that transports the methylmercury–L-cysteine complex; however, the mechanism by which it is released from the endothelial cells into brain interstitial space is unknown. Using bovine brain capillary endothelial cells in culture, the present study examined the hypothesis that methylmercury is transported out of these cells as a glutathione (GSH) complex. GSH concentration in cultured bovine brain capillary endothelial cells was 13.1 ± 3.3 nmol/mg protein. Depletion of intracellular GSH in [203Hg]methylmercury-preloaded cells by exposure to 1-chloro-2,4-dinitrobenzene or diethyl maleate decreased the rate of [203Hg]methylmercury efflux. Incubation of [203Hg]methylmercury-preloaded cells with high concentrations ofS-methylglutathione,S-ethylglutathione,S-butylglutathione, and sulfobromophthalein–glutathione inhibited [203Hg]methylmercury efflux. The GSH analogs γ-glutamylglycylglycine and ophthalmic acid also inhibited [203Hg]methylmercury efflux, but to a lesser degree than the glutathioneS-conjugates, whereasL-leucine,L-methionine, andL-alanine had no effect. Efflux was not affected by depletion of intracellular ATP with 2-deoxyglucose or antimycin A. These results indicate that complexation with GSH and subsequent transport of the complex by an ATP-independent mechanism may be involved in the transport of methylmercury out of brain capillary endothelial cells.

Studies on the Basis for the Toxicity of Acrolein Mercapturates

Acrolein, 3-oxopropyl glutathione (oxoPrGSH), andS-3-hydroxypropylN-acetylcysteine (hydroxyPrMCA) are confirmed metabolic products of cyclophosphamide. Other potential metabolites include the mercapturic acidS-3-oxopropylN-acetylcysteine (oxo- PrMCA), its sulfoxide, and their corresponding diacid forms. The reactivity of acrolein would appear to preclude its movement from the main site of formation (liver) to the sites of toxicity (lung and bladder). However, the rerelease of acrolein from various thiol conjugates via a β-elimination reaction is possible. It is also possible that the parent conjugate is directly toxic. The current study examined the toxicity of various acrolein–thiol conjugates and related analogs to human lung adenoma A549 cells. The expected enhancement of acrolein, oxoPrMCA, and oxoPrMCAS-oxide toxicity (assessed as cell proliferation by the alamarBlue assay) following a 2-hr exposure of cells treated with diethyl maleate (DEM) to deplete GSH was observed. OxoPrGSH was toxic when present for 24 hr, and this toxicity was also enhanced by pretreatment with DEM. When treated with these conjugates alone, the depletion of intracellular GSH only occurred at doses above those needed to significantly inhibit cell proliferation. There were no changes in protein thiols as determined using the membrane impermeant fluorescent thiol probepara-sulfobenzoyloxybromobimane. The diacid conjugate was not toxic to A549 cells indicating further oxidation products of the mercapturic acids are not a factor in toxicity. ButanoneMCA, an analog of oxoPrMCA that cannot exist in the geminal diol form, inhibited A549 cell growth only slightly less effectively than oxoPrMCA, suggesting the geminal diol is not toxicologically significant. OxoBuMCA, which cannot undergo β-elimination of acrolein, showed no toxicity to these cells, suggesting that the release of acrolein could be required. Exogenous GSH provided protection from all toxic compounds suggesting that the toxic species is electrophilic. Overall, the data suggest that toxicity, in terms of an inhibition of cell proliferation, is not due to the parent molecule but rather is the result of rereleased acrolein that then affects factors necessary for cell proliferation.

Effects of glutathione and pH on the oxidation of biomarkers of cellular oxidative stress.

Cellular oxidative stress is associated with such pathological conditions as arteriosclerosis, inflammatory diseases and cancer. The oxidation of the biomarkers. 2',7'-dichlorofluorescin (DCFH), 2-deoxyribose, and lipid peroxidation are often used to assess the status of oxidative stress in cells and tissues. Since high levels of reduced glutathione (GSH) and acidic conditions have been associated with diminished chemical lethality, we evaluated the influence of these parameters on the cellular response to oxidative stress. We used a cultured hepatocyte line (ch/ch cells) that is susceptible to oxidative toxicity. A hydroxyl radical-generating system consisting of H2O2, ascorbate and iron produced a pH-dependent lethality, with complete cell killing at pH 7.4 and none at pH 6.8. Lethality correlated with the depletion of intracellular GSH, and with an increase in DNA fragmentation. The influence of GSH and pH was assessed for DCFH and 2-deoxyribose oxidation, and for lipid peroxidation. The oxidation of DCFH and 2-deoxyribose was inhibited by GSH, with about 4-fold greater inhibition efficacy at pH 6.8 than at pH 7.4 [IC50 values (microM GSH) for pH 6.8 and 7.4, respectively: DCFH = 7 and 30; 2-deoxyribose = 125 and 490]. GSH did not affect lipid peroxidation at either pH, even at a high intracellular concentration of 10 mM. We conclude: 1) GSH is not inhibiting DCFH and 2-deoxyribose oxidation by simply quenching reactive oxygen (hydroxyl radical or perferryl oxygen), since GSH did not inhibit lipid peroxidation: 2) the protonated form GSH is more likely to be the inhibitory species rather than GS-, since even in the simple cell-free systems lower pH inhibited biomarker oxidation; and; 3) hydroxyl radical may not be the primary intracellular oxidant of DCFH, since intracellular GSH concentrations are typically 10- to 100-fold higher than the IC50 values for GSH inhibiting reactive oxygen-mediated DCFH oxidation.