Glutathione and glutathione conjugate efflux from cultured liver cells

Efflux of glutathione (GSH) and GSH-conjugates from cultured rat liver epithelial cell lines; the non-tumorigenic ARL-15C₁ and the -glutamyl transpeptidase containing, tumorigenic ARL-16T₂, has been assessed under basal condition and during chronic treatment with 75 and 150 M ethacrynic acid (EA). The intracellular level of GSH increased in proportion to EA concentration during chronic exposure. The rates of GSH and GSH-EA conjugate efflux increased with intracellular GSH in both ARL cell lines.Glutathione-S-transferase activity measured with EA as substrate increased over the experimental time course after treatment with 150, but not 75 M EA. When intracellular GSH content was increased by treatment with the cysteine pro-drug, 2-L-oxothiazolidine 4-carboxylic acid, the rate of GSH efflux was increased, but not the rate of GS-EA conjugate export. Inhibition of -glutamyl transpeptidase by acivicin (AT-125) increased the GSH and GS-EA conjugate efflux rate in ARL-16T₂ cells by factors of approximately 2 and 15, respectively. Acivicin treatment of ARL-16T₂ cells chronically treated with EA elevated GSH efflux rate by 10-fold and GS-EA efflux by 40-fold versus control samples. These studies show that GSH and GSH conjugate efflux are accomplished as independently regulated processes. Efflux of GSH is enhanced by increased in racellular GSH, but increase in the conjugate transport rate requires the presence of the GSH conjugate. The response of the efflux process to treatment with a chronic GSH depleting agent was identical in two cell lines in which the metabolic fate of glutathione is known to differ fundamentally.Abbreviations GSH reduced glutathione - GSSG oxidized glutathione - GS-EA the glutathione conjugate of ethacrynic acid - EA ethacrynic acid - CDNB 1-chloro 2,4-dinitrobenzene - HBS HEPES buffered saline - OTC 2-L-oxothiazolidine 4-carboxylic acid - CYSSG cysteinyl-glutathione mixed disulfide - FDNB 1-fluoro-2,4-dinitrobenzene - GCS -glutamyl cysteine synthetase - GST glutathione-S-transferase - BCA bicinchoninic acid - SDS sodium dodecyl sulfate - PCA perchloric acid     

Increased efflux of oxidized glutathione (GSSG) causes glutathione depletion and potentially diminishes antioxidant defense in sickle erythrocytes

Erythrocytes are both an important source and target of reactive oxygen species in sickle cell disease. Levels of glutathione, a major antioxidant, have been shown to be decreased in sickle erythrocytes and the mechanism leading to this deficiency is not known yet. Detoxification of reactive oxygen species involves the oxidation of reduced glutathione (GSH) into glutathione-disulfide (GSSG) which is actively transported out of erythrocyte. We questioned whether under oxidative conditions, GSSG efflux is increased in sickle erythrocytes. Erythrocytes of 18 homozygous sickle cell patients and 9 race-matched healthy controls were treated with 2,3-dimethoxy-l,4-naphthoquinone, which induces intracellular reactive oxygen species generation, to stimulate GSSG production. Intra- and extracellular concentrations of GSH and GSSG were measured at baseline and during 210-minute 2,3-dimethoxy-l,4-naphthoquinone stimulation. While comparable at baseline, intracellular and extracellular GSSG concentrations were significantly higher in sickle erythrocytes than in healthy erythrocyte after 210-minute 2,3-dimethoxy-l,4-naphthoquinone stimulation (69.9 ± 3.7 μmol/l vs. 40.6 ± 6.9 μmol/l and 25.8 ± 2.7 μmol/l vs. 13.6 ± 1.7 μmol/l respectively, P<0.002). In contrast to control erythrocytes, where GSH concentrations remained unchanged (176 ± 8.4 μmol/l vs. 163 ± 13.6 μmol/l, NS), GSH in sickle erythrocytes decreased significantly (from 167 ± 8.8 μmol/l to 111 ± 11.8 μmol/l, P<0.01) after 210-minute 2,3-dimethoxy-l,4-naphthoquinone stimulation. Adding multidrug resistance-associated protein-1 inhibitor (MK571) to erythrocytes blocked GSSG efflux in both sickle and normal erythrocytes. GSSG efflux, mediated by multidrug resistance-associated protein-1, is increased in sickle erythrocytes, resulting in net loss of intracellular glutathione and possibly higher susceptibility to oxidative stress.     

Hormonal regulation of glutathione efflux

The efflux of GSH has been shown previously to be a saturable process in both isolated rat hepatocytes and perfused liver, suggesting a carrier-mediated transport mechanism. The possibility in hormonal regulation of this process has been raised by recent reports. Our present work examined the role of hormones known to affect intracellular signal transduction mechanisms on GSH efflux in cultured rat hepatocytes and perfused rat livers. We found that cAMP-dependent factors, such as cholera toxin (CT), dibutyryl cAMP, forskolin, and glucagon all stimulated GSH efflux in cultured rat hepatocytes. The efflux kinetics were compared in cultured cells incubated with or without CT; the stimulation of GSH efflux was related to a near doubling of the Vmax while exhibiting no significant alteration of the Km. The increase in intracellular cAMP level associated with the threshold for this stimulatory effect was 25% above control. The stimulatory effect of CT could not be blocked by cyclohexamide pretreatment or reversed by colchicine treatment. The stimulatory effect of glucagon was abolished in the presence of ouabain but not in the presence of barium. On the other hand, hormones which act through Ca2+ and protein kinase C, such as phenylephrine and vasopressin, had no effect on GSH efflux in the cultured cells. In the perfused liver model, glucagon (10 nM) and dibutyryl cAMP (8 microM) stimulated sinusoidal GSH efflux to 130 and 144% of control values, respectively, and increased bile flow while not affecting biliary GSH efflux. Finally, the physiological significance of glucagon-mediated stimulation of sinusoidal GSH efflux was assessed by both plasma GSH and glucose levels in response to in vivo glucagon infusion. The threshold dose of glucagon for significant increase in plasma GSH (5.21 pmol/min) was lower than for glucose (15.61 pmol/min). At the highest glucagon infusion rate (261 pmol/min), plasma GSH level doubled while glucose level increased 80%. In conclusion, increased cAMP stimulates GSH efflux in cultured rat hepatocytes and perfused livers. The stimulatory effect of cAMP is exerted at the sinusoidal pole and appears to be mediated by hyperpolarization of hepatocytes by stimulation of Na(+)-K(+)-ATPase. In vivo studies confirmed the importance of cAMP-mediated stimulation of sinusoidal GSH efflux as it resulted in significant elevation of the plasma GSH level.     

Dynamics of glutathione conjugation and conjugate efflux in detoxification of the carcinogen, 4-nitroquinoline 1-oxide: contributions of glutathione, glutathione S-transferase, and MRP1

4-Nitroquinoline 1-oxide (NQO) is a reactive electrophile with potent cytotoxic as well as genotoxic activities. NQO forms a conjugate, QO-SG, with glutathione, which greatly reduces its chemical reactivity. Previous studies demonstrated that glutathione S-transferase (GST) P1a-1a and multidrug resistance protein (MRP) 1/2 act in synergy to confer resistance to both cyto- and genotoxicities of NQO, whereas protection afforded by GSTP1a-1a or MRP alone was much less. To better understand the role of glutathione, GSTP1a-1a, and MRP1 in NQO detoxification, we have characterized the kinetics and cofactor requirements of MRP1-mediated transport of QO-SG and NQO. Additionally, using recombinant GSTP1a-1a and physiological conditions, we have examined the enzymatic and nonenzymatic formation of QO-SG. Results show that MRP1 supports efficient transport of QO-SG with a K(m) of 9.5 microM and a V(max) comparable to other good MRP1 substrates. Glutathione or its S-methyl analogue enhanced the rate of (3)H-QO-SG transport, whereas QO-SG inhibited the rate of (3)H-glutathione transport. These data favor a mechanism for glutathione-enhanced, MRP1-mediated QO-SG transport that does not involve cotransport of glutathione. NQO was not transported by MRP1 either alone or in the presence of S-methyl glutathione. Transport of (3)H-NQO was observed in the presence of glutathione, but uptake into MRP1-containing vesicles was entirely attributable to its conjugate, QO-SG, formed nonenzymatically. While the nonenzymatic rate was readily measurable, enzyme catalysis was overwhelmingly dominant in the presence of GSTP1a-1a (rate enhancement factor, (k(cat)/K(m))/k(2), approximately 3 x 10(6)). We conclude that MRP1 supports detoxification of NQO via efficient, glutathione-stimulated efflux of QO-SG. While nonenzymatic QO-SG formation and MRP1-mediated conjugate efflux result in low-level protection from cyto- and genotoxicities, this protection is greatly enhanced by coexpression of GSTP1-1 with MRP1. This result emphasizes the quantitative importance of enzyme-catalyzed conjugate formation, a crucial determinant of high-level, MRP-dependent protection of cells from NQO toxicity.     

Dissection of glutathione conjugate turnover in yeast

Xenobiotics are widely used as pesticides. The detoxification of xenobiotics frequently involves conjugation to glutathione prior to compartmentalization and catabolism. In plants, degradation of glutathione-S-conjugates is initiated either by aminoterminal or carboxyterminal amino acid cleavage catalyzed by a γ-glutamyl transpeptidase and phytochelatin synthase, respectively. In order to establish yeast as a model system for the analysis of the plant pathway, we used monochlorobimane as a model xenobiotic in Saccharomyces cerevisiae and mutants thereof. The catabolism of monochlorobimane is initiated by conjugation to form glutathione-S-bimane, which is then turned over into a γ-GluCys-bimane conjugate by the vacuolar serine carboxypeptidases CPC and CPY. Alternatively, the glutathione-S-bimane conjugate is catabolized by the action of the γ-glutamyl transpeptidase Cis2p to a CysGly-conjugate. The turnover of glutathione-S-bimane was impaired in yeast cells deficient in Cis2p and completely abolished by the additional inactivation of CPC and CPY in the corresponding triple knockout. Inducible expression of the Arabidopsis phytochelatin synthase AtPCS1 in the triple knockout resulted in the turnover of glutathione-S-bimane to the γ-GluCys-bimane conjugate as observed in plants. Challenge of AtPCS1-expressing yeast cells with zinc, cadmium, and copper ions, which are known to activate AtPCS1, enhanced γ-GluCys-bimane accumulation. Thus, initial catabolism of glutathione-S-conjugates is similar in plants and yeast, and yeast is a suitable system for a study of enzymes of the plant pathway.     

Arsenate V induced glutathione efflux from human erythrocytes

ObjectiveThe objective of the present study was to investigate if arsenate V exposure results in glutathione efflux from human erythrocytes.ProcedureThe changes in intracellular and extracellular nonprotein sulfhydryl and glutathione levels were determined in arsenate (V) exposed erythrocytes. Presence of any cellular membrane damage was assessed by lactate dehydrogenase activity measurement in the supernatant.ResultsWhen erythrocytes were exposed to 10 mM of arsenate (V) for 4 h, the intracellular NPSH level decreased to 0.28 ± 0025 μmol/ml erythrocyte. In contrast, extracellular nonprotein thiol level was increased to 0.180 ± 0.010 μmol/ml erythrocyte in 4 h. Extracellular glutathione levels reached to 0.028 ± 0.001, 0.052 ± 0.002, and 0.054 ± 0.004 μmol/ml erythrocyte with 1, 5, and 10 mM of arsenate (V), respectively. Utilization of MK571 a multi drug resistance-associated protein 1 inhibitor decreased the rate of glutathione efflux from erythrocytes suggesting a role for this membrane transporter in the process.ConclusionThe results of the present study indicate that erythrocytes efflux glutathione when exposed to arsenate (V).     

The role of glutathione conjugate metabolism and cysteine conjugate beta-lyase in the mechanism of S-cysteine conjugate toxicity in LLC-PK1 cells

A cell line derived from pig kidney, LLC-PK1, was grown in a culture system in which the cells express morphological and biochemical characteristics of the proximal tubule. This model was used to investigate the mechanism of S-cysteine conjugate toxicity and the role of glutathione conjugate metabolism. LLC-PK1 cells have the degradative enzymes of the mercapturate pathway, and S-(1,2-dichlorovinyl)-L-cysteine and S-(1,2-dichlorovinyl)-L-glutathione are toxic. S-(1,2-Dichlorovinyl)-L-glutathione is not toxic when the cells are pretreated with AT-125, an inhibitor of gamma-glutamyl transpeptidase. The cells respond to a variety of toxic cysteine conjugates. Cysteine conjugate beta-lyase activity is not detectable by standard assays, but can be measured using radiolabeled S-(1,2-dichlorovinyl)-L-cysteine. Pyruvate stimulates the beta-elimination reaction with S-(1,2-dichlorovinyl)-L-cysteine as substrate 2-3-fold. The data suggest that a side transamination reaction regulates the flux of substrate through the beta-elimination pathway; therefore, cysteine conjugate beta-lyase in LLC-PK1 cells may be regulated by transamination, and measurement of lyase activity in some systems may require the presence of alpha-ketoacids. Aminoxyacetic acid blocks both the metabolism of S-(1,2-dichlorovinyl)-L-cysteine to a reactive species which covalently binds to cellular macromolecules and toxicity. Glutathione inhibits the binding of the sulfur containing cleavage fragment to acid insoluble material in vitro. The data provide direct evidence that S-(1,2-dichlorovinyl)-L-cysteine is metabolized to a reactive species which covalently binds to cellular macromolecules, and the binding is proportional to toxicity.     

Diphenyleneiodonium triggers the efflux of glutathione from cultured cells

Diphenyleneiodonium (DPI) is a broad-spectrum flavoprotein inhibitor commonly used to inhibit oxidant production by the NADPH oxidase of phagocytic and nonphagocytic cells. A previous study has shown that DPI can sensitize T24 bladder carcinoma cells to Fas-mediated apoptosis. We observed DPI to deplete intracellular reduced glutathione (GSH) in T24 cells and a range of other primary and transformed cell types. The effect was immediate, with 50% loss of intracellular GSH within 2 h of treatment with DPI. The glutathione was quantitatively recovered in the extracellular medium, indicating that efflux was occurring. The loss of GSH was blocked with bromosulfophthalein, an inhibitor of the canalicular GSH transporters. We conclude that DPI induces a dramatic efflux of cellular GSH from T24 cells via a specific transport channel. This provides a potential mechanism for its proapoptotic effect, and it also has important implications for the regulation of glutathione homeostasis in cells.     

Vacuolar transport of the glutathione conjugate of trans-cinnamic acid

Red beet (Beta vulgaris L.) tonoplast membrane vesicles and [14C]trans-cinnamic acid-glutatione were used to study the vacuolar transport of phynylpropanoid-glutathione conjugates which are formed in peroxidase-mediated reactions. It was determined that the uptake of [14C]trans-cinnamic acid-glutathione into the tonoplast membrane vesicles was MgATP dependent and was 10-fold faster than the uptake of non-conjugated [14C]trans-cinnamic acid. Uptake of the conjugate in the presence of MgATP was not dependent on a trans-tonoblast H+-electrochemical gradient, because uptake was not affected by the addition of NH4Cl (1 mM; 0% inhibition) and was only slightly affected by gramicidin-D (5 microM; 14% inhibition). Uptake of the conjugate was inhibited 92% by the addition of vanadate (1 mM) and 71% by the addition of the model substrate S-(2,4-dinitrophenyl) glutathione (500 microM). Uptake did not occur when a nonhydrolyzable analog of ATP was used in place of MgATP. The calculated Km and Vmax values for uptake were 142 microM amd 5.95 nmol mg(-1) min(-1), respectively. Based on these results, phenylpropanoid-glutation conjugates formed in peroxidase-mediated reactions appear to be transported into the vacuole by the glutathione S-conjugate pump(s) located in the tonoplast membrane.     

Searching for mechanisms of N-methyl-D-aspartate-induced glutathione efflux in organotypic hippocampal cultures

N-Methyl-d-aspartate (NMDA)-receptor stimulation evoked a selective and partly delayed elevated efflux of glutathione, phosphoethanolamine, and taurine from organotypic rat hippocampus slice cultures. The protein kinase inhibitors H9 and staurosporine had no effect on the efflux. The phospholipase A₂ inhibitors quinacrine and 4-bromophenacyl bromide, as well as arachidonic acid, a product of phospholipase A₂ activity, did not affect the stimulated efflux. Polymyxin B, an antimicrobal agent that inhibits protein kinase C, and quinacrine in high concentration (500 µM), blocked efflux completely. The stimulated efflux after but not during NMDA incubation was attenuated by a calmodulin antagonist (W7) and an anion transport inhibitor (DNDS). Omission of calcium increased the spontaneous efflux with no or small additional effects by NMDA. In conclusion, NMDA receptor stimulation cause an increased selective efflux of glutathione, phosphoethanolamine and taurine in organotypic cultures of rat hippocampus. The efflux may partly be regulated by calmodulin and DNDS sensitive channels.     

Increased efflux rather than oxidation is the mechanism of glutathione depletion by 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)

Incubation of isolated hepatocytes in the presence of either the parkinsonian-inducing compound 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) or its putative toxic metabolite 1-methyl-4-phenylpyridinium ion (MPP+) led to a depletion of intracellular reduced glutathione (GSH), which was mostly recovered as glutathione disulfide (GSSG). However, both MPTP- and MPP+-induced glutathione perturbances were relatively unaffected by the prior inhibition of glutathione reductase with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), suggesting that intracellular oxidation was not the major mechanism involved in the GSH loss. Inclusion of cystine in the incubation mixtures revealed a time-dependent formation of cysteinyl glutathione (CySSG), indicating that an increased efflux was mostly responsible for the MPTP- and MPP+-induced GSH depletion. Therefore, the measurement of GSSG, which is apparently formed extracellularly, was not associated with oxidative stress.     

Activation potassium efflux from Escherichia coli by glutathione metabolites

The mechanism by which N-ethylmaleimide (NEM) elicits potassium efflux from Escherichia coli has been investigated. The critical factor is the formation of specific glutathione metabolites that activate transport systems encoded by the kefB and kefC gene products. Formation of N-ethyl-succinimido-S-glutathione (ESG) leads to the activation of potassium efflux via these transport systems. The addition of dithiothreitol and other reducing agents to cells reverses this process by causing the breakdown of ESG and thus removing the activator of the systems. Chlorodinitrobenzene, p-chloromercuribenzoate and phenylmaleimide provoke similar effects to NEM. lodoacetate, which leads to the formation of S-carboxymethyl-glutathione, does not activate the systems but does prevent the action of NEM. It is concluded that the KefB and KefC systems are gated by glutathione metabolites and that the degree to which they are activated is dependent upon the nature of the substituent on the sulphydryl group.     

Inhibition of glutathione efflux from isolated rat hepatocytes by methionine

A substantial inhibition (50-70%) of GSH efflux by methionine was demonstrated in hepatocytes isolated from fed rats. Concurrent measurements of intracellular GSH revealed maintenance of a higher concentration in methionine-supplemented cells over the 1-h incubation. Analysis of total GSH suggested that maintenance of higher intracellular GSH by methionine could be quantitatively accounted for by inhibition of GSH efflux rather than by net GSH synthesis. This conclusion was supported by studies with propargylglycine, a potent inhibitor of cysteine synthesis from methionine. Identical results were obtained in incubations containing either propargylglycine and methionine or methionine alone, thereby suggesting that net synthesis of GSH from methionine was minimal under the assay conditions. Similar decreases (40-60%) in the rate of extracellular accumulation of GSH were observed with ethionine and buthionine, two higher homologs of methionine, but not with a wide range of other naturally occurring and synthetic amino acids. The inhibition of GSH efflux by methionine was not dependent on the presence of sodium in the medium and did not correlate with metabolic consumption of ATP.     

Active site-directed irreversible inhibition of glutathione S-transferases by the glutathione conjugate of tetrachloro-1,4-benzoquinone

Purified glutathione S-transferase from rat liver cytosol are irreversibly inhibited by the glutathione conjugate of tetrachloro-1,4-benzoquinone, 2-S-glutathionyl-3,5,6-trichloro-1,4-benzoquinone. The inhibition is due to covalent binding in or near the active site, resulting in modification of a single amino acid residue/subunit, presumably a cysteine residue. The amount of inhibition is related to the molar ratio of the inhibitor and the enzyme and is independent of the enzyme concentration. A 70-80% inhibition is obtained on incubating the enzyme with a 5-fold molar excess of the conjugate. Complete 100% inhibition is never reached. The derivative bound to the enzyme still possesses a quinone structure and is able to react with thiol-containing compounds. Reduction of the enzyme-bound quinone abolishes its reactivity but does not decrease the inhibition. At 0 degrees C, the glutathione conjugate of tetrachloro-1,4-benzoquinone inhibits the glutathione S-transferases at a much higher rate than the corresponding beta-mercaptoethanol conjugate, indicating a distinct targetting effect of the glutathione moiety. However, the parent compound, tetrachloro-1,4-benzoquinone, also has a considerable affinity for the enzymes. Although it does not react as fast as the glutathione conjugate, it reacts with the same amino acid residue. Protection from inhibition by the substrate analog S-hexylglutathione also indicates an active site-directed modification. Small but significant differences exist between the different rat liver transferase isoenzymes; using a 20-fold molar excess the inhibition ranges from 78 to 98% for the conjugate, and from 72 to 93% for the quinone, with isoenzyme 1-1 being the most and isoenzyme 2-2 the least inhibited forms.     

Characterization of the glutathione conjugate of the semisynthetic flavonoid monoHER

Flavonoids protect against oxidative stress by scavenging free radicals. During this protection flavonoids are oxidized. The oxidized flavonoids formed are often reactive. Consequently, protection by flavonoids can result in the formation of toxic products. In this study the oxidation of 7-mono-O-(β-hydroxyethyl)rutoside (monoHER), which is a constituent of the registered drug Venoruton, was studied in the absence and presence of glutathione (GSH). MonoHER was oxidized by horseradish peroxidase/H₂O₂. Spectrophotometric and HPLC analysis showed that in the presence of GSH, a monoHER–GSH conjugate was formed, which was identified as 2′-glutathionyl monohydroxyethylrutoside by mass spectrometric analysis and ¹H NMR. Preferential formation of this glutathione adduct in the B ring at C2′ was confirmed by molecular quantum chemical calculations. This conjugate was also detected in the bile fluid of a healthy volunteer after iv administration of monoHER, demonstrating its formation in vivo. These results indicate that in the process of offering protection against free radicals, monoHER is converted into an oxidation product that is reactive toward thiols. The formation of this thiol-reactive oxidation product is potentially harmful. Thus, the supposed beneficial effect of monoHER as an antioxidant may be accompanied by the formation of products with an electrophilic, toxic potential.     

MicroRNA-133a regulates DNA methylation in diabetic cardiomyocytes

We tested the hypothesis that miR-133a regulates DNA methylation by inhibiting Dnmt-1 (maintenance) and Dnmt-3a and -3b (de novo) methyl transferases in diabetic hearts by using Ins2(+/-) Akita (diabetic) and C57BL/6J (WT), mice and HL1 cardiomyocytes. The specific role of miR-133a in DNA methylation in diabetes was assessed by two treatment groups (1) scrambled, miR-133a mimic, anti-miR-133a, and (2) 5mM glucose (CT), 25mM glucose (HG) and HG+miR-133a mimic. The levels of miR-133a, Dnmt-1, -3a and -3b were measured by multiplex RT-PCR, qPCR and Western blotting. The results revealed that miR-133a is inhibited but Dnmt-1 and -3b are induced in Akita suggesting that attenuation of miR-133a induces both maintenance (Dnmt-1) - and de novo - methylation (Dnmt-3b) in diabetes. The up regulation of Dnmt-3a in Akita hearts elicits intricate and antagonizing interaction between Dnmt-3a and -3b. In cardiomyocytes, over expression of miR-133a inhibits but silencing of miR-133a induces Dnmt-1, -3a and -3b elucidating the involvement of miR-133a in regulation of DNA methylation. The HG treatment up regulates only Dnmt-1 and not Dnmt-3a and -3b suggesting that acute hyperglycemia triggers only maintenance methylation. The over expression of miR-133a mitigates glucose mediated induction of Dnmt-1 illustrating the role of miR-133a in regulation of DNA methylation in diabetes.     

Increased glutathione content in yeastSaccharomyces cerevisiae exposed to NaCl

Glutathione is one of the major antioxidant molecules of cells and is thought to play a vital role in buffering the cell against reactive oxygen species and toxic electrophiles. Since an overlap between osmotic and oxidative stress response is already know, the aim of the work was to determine the role of glutathione in yeast stress response to NaCl. YeastSaccharomyces cerevisiae ZIM 2155 was exposed to NaCl in concentration of 1–8% (w/v). Measuring cell cultivability showed a significant decrease appeared in cell exposed to 5–8% NaCl for 1 h. Cultivable cells were about 50% of control. Increased production of reactive oxygen species in cells exposed to 6, 7 and 8% NaCl for 1 h (1.3-fold, 1.9-fold and 2.8-fold increase, respectively) led to elevated glutathione content in reduce d form (119.1%, 122.6%, 141.5%, respectively). Two hours from NaCl addition intracellular oxidant level was slightly elevated compared to 1-h exposure, while glutathione content in reduced form was almost the same. We demonstrated that glutathione plays an important role in yeast stress response to NaCl.