Unique characteristics of rat spleen lymphocyte, L1210 lymphoma and HeLa cells in glutathione biosynthesis from sulfur-containing amino acids

Suspensions of rat spleen lymphocyte, murine L1210 lymphoma and HeLa cells were partially depleted of glutathione (GSH) with diethyl maleate and allowed to utilize either [35S]methionine, [35S]cystine or [35S]-cysteine for GSH synthesis. Lymphocytes preferentially utilized cysteine, compared to cystine, at a ratio of about 30 to 1, which was not related to differences in the extent of amino acid uptake. Only HeLa cells displayed a slight utilization of methionine via the cystathionine pathway for cysteine and GSH biosynthesis. HeLa and L1210 cells readily utilized either cystine or cysteine for GSH synthesis. The three cell types accumulated detectable levels of intracellular cysteine glutathione mixed disulfide when incubated in a medium containing a high concentration of cystine. Various enzyme activities were measured including gamma-glutamyl transpeptidase, GSH S-transferase and gamma-cystathionase. These results support the concept of a dynamic interorgan relationship of GSH to plasma cyst(e)ine that may have importance for growth of various cell types in vivo.     

Glutathione depletion by DL-buthionine-SR-sulfoximine (BSO) potentiates X-ray-induced chromosome lesions after liquid holding recovery

The impact of intracellular glutathione depletion on chromosome damage induced by X irradiation under aerobic conditions was investigated in two different cell lines, Ehrlich ascites tumor cells (EATC) and Chinese hamster ovary cells (CHO-K1). Thiol-depleted cell cultures in plateau phase were obtained by prolonged incubation in growth medium containing DL-buthionine-SR-sulfoximine (BSO), a specific inhibitor of gamma-glutamyl-cysteine synthetase. Cells were then assayed using the procedures of G. L. Ellmann (Arch. Biochem. Biophys. 82, 70-77 (1959)), F. Tietze (Anal. Biochem. 27, 502-522 (1969)), and J. Sedlack and R.H. Lindsay (Anal. Biochem. 25, 192-205 (1968)) for non-protein bound SH (NPSH), glutathione (GSH), and total SH (TSH). In both cell lines GSH was reduced to less than 10% of controls at higher BSO concentrations around 1 mM, whereas TSH and NPSH were affected to only 40-60%. In EATC pretreated with up to 1 mM BSO for 72 h, increased levels of spontaneously occurring micronuclei were found. At BSO concentrations above 200 microM, both cell lines showed a potentiation of chromosome lesions scored as micronuclei and induced under aerobic X irradiation when liquid holding recovery in the original nutrient-depleted medium was performed; the extent of chromosome damage eventually reached that which could be obtained by application of beta-arabinofuranosyladenine (beta-araA), known to inhibit DNA repair processes by blocking DNA polymerases. It is therefore suggested that GSH depletion causes impairment of repair of lesions leading to chromosome deletions and subsequently to micronuclei. In contrast to CHO cell cultures, EATC showed a reversion of the potentiation effect as indicated by a decrease in the micronucleus content during prolonged incubation in the presence of BSO in the millimolar range. This effect could not be correlated to the remaining GSH content of less than 10% but may be due to some accumulation of unknown NPSH components. Since addition of L-cysteine to EATC cultures pretreated with BSO decreased the micronucleus content, cysteine/cystine or a related thiol within the NPSH fraction may be involved in the reestablishment of repair. Thus at least in one cell line, a rather complex response to BSO administration indicated that not only GSH but also other thiols may determine the level of chromosome damage after liquid holding recovery.     

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

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

Glutathione modulates lipid composition of human colon derived HT-29 cells

Glutathione (GSH) is important in maintaining intracellular thiol status. The present study looked at the effect of GSH depletion on lipid composition of colon-derived HT-29 cells. GSH was depleted in HT-29 cells by incubation either with buthionine-S, R-sulfoximine (BSO) or diethylmaleate (DEM). GSH was restored during early periods of cell growth by supplementation of growth medium with either GSH ester or N-acetyl cysteine (NAC). Lipids were analysed following GSH depletion and supplementation. Among the neutral lipids, an increase in free cholesterol and diacylglycerol and decrease in cholesteryl ester and triacylglycerol were seen in GSH-depleted cells as compared to control cells. There were no detectable free fatty acids either in control or GSH-depleted cells. Among the phospholipids, a decrease in phosphatidylcholine and phosphatidylinositol and an increase in phosphatidylethanolamine were observed. These changes were almost completely reversed by supplementation of BSO-treated cells with GSH ester and partially reversed by N-acetyl cysteine. These results suggest that the GSH status of the cell plays an important role in the lipid composition of the cells.     

Altered differentiation in rat and rabbit limb bud micromass cultures by glutathione modulating agents

Glutathione (GSH) is the primary source of reducing equivalents in most cells, contributes significantly to the cellular redox potential and can control differentiation, proliferation, and apoptosis. Using limb bud micromass cultures from Sprague Dawley rats and New Zealand White rabbits, GSH modulating agents, L-buthionine-S,R-sulfoximine (BSO) and diethyl maleate (DEM) altered the formation of Alcian blue positive chondrogenic foci. Limb bud micromass cultures were treated for 5 d with BSO (50 or 100 μM) or DEM (5–25 μM). GSH content was determined by HPLC analysis. In rat cultures, BSO treatment did not affect differentiation but did show GSH depletion. In rabbit cultures, BSO completely inhibited differentiation and significantly depleted GSH. Treatment of rat cultures with DEM resulted in the dose-dependent decrease of chondrogenic foci, which correlated with a dose-dependent depletion of GSH. DEM completely inhibited rabbit limb bud cell differentiation and depleted GSH by 44%. Inhibition of differentiation was confirmed in rabbit cultures by the reduction in BMP-4 content. Addition of N-acetylcysteine to rabbit micromass cultures restored chondrogenic foci differentiation seen following treatment with both DEM and BSO. These results show species differences in GSH depletion in rat vs. rabbit limb bud cells and implicate GSH and cysteine in affecting pathways involved in chondrocyte differentiation.     

A novel approach to enhancing cellular glutathione levels

GSH and GSH-associated metabolism provide the major line of defense for the protection of cells from oxidative and other forms of toxic stress. Of the three amino acids that comprise GSH, cysteine is limiting for GSH synthesis. As extracellularly cysteine is readily oxidized to form cystine, cystine transport mechanisms are essential to provide cells with cysteine. Cystine uptake is mediated by system x(c)(-), a Na(+)-independent cystine/glutamate antiporter. Inhibition of system x(c)(-) by millimolar concentrations of glutamate, a pathway termed oxidative glutamate toxicity, results in GSH depletion and nerve cell death. Recently, we described a series of compounds derived from the conjugation of epicatechin (EC) with cysteine and cysteine derivatives that protected nerve cells in culture from oxidative glutamate toxicity by maintaining GSH levels. In this study, we characterize an additional EC conjugate, cysteamine-EC, that is 5- to 10-fold more potent than the earlier conjugates. In addition, we show that these EC conjugates maintain GSH levels by enhancing the uptake of cystine into cells through induction of a disulfide exchange reaction, thereby uncoupling the uptake from system x(c)(-). Thus, these novel EC conjugates have the potential to enhance GSH synthesis under a wide variety of forms of toxic stress.     

Toxic effects of acute glutathione depletion by buthionine sulfoximine and dimethylfumarate on murine mammary carcinoma cells

Glutathione (GSH) depletion to approximately equal to 5% of control for 48 h or longer by 0.05 mM L-buthionine sulfoximine (BSO) led to appreciable toxicity for the 66 murine mammary carcinoma cells growing in vitro [L.A. Dethlefsen et al., Int. J. Radiat. Oncol. Biol. Phys. 12, 1157-1160 (1986)]. Such toxicity in normal, proliferating cells in vivo would be undesirable. Thus the toxic effects after acute GSH depletion to approximately equal to 5% of control by BSO plus dimethylfumarate (DMF) were evaluated in these same 66 cells to determine if this anti-proliferative effect could be minimized. Two hours of 0.025 mM DMF reduced GSH to 45% of control, while 6 h of 0.05 mM BSO reduced it to 16%. However, BSO (6 h) plus DMF (2 h) and BSO (24 h) plus DMF (2 h) reduced GSH to 4 and 2%, respectively. The incorporation (15-min pulses) of radioactive precursors into protein and RNA were unaffected by these treatment protocols. In contrast, cell growth was only modestly affected, but the incorporation of [3H]thymidine into DNA was reduced to 64% of control by the BSO (24 h) plus DMF (2 h) protocol even though it was unaffected by the BSO (6 h) plus DMF (2 h) treatment. The cellular plating efficiencies from both protocols were reduced to approximately equal to 75% of control cells. However, the aerobic radiation response, as measured by cell survival, was not modified at doses of either 4.0 or 8.0 Gy. The growth rates of treated cultures, after drug removal, quickly returned to control rates and the resynthesis of GSH in cells from both protocols was also rapid. The GSH levels after either protocol were slightly above control by 12 h after drug removal, dramatically over control (approximately equal to 200%) by 24 h, and back to normal by 48 h. Thus even a relatively short treatment with BSO and DMF resulting in a GSH depletion to 2-5% of control had a marked effect on DNA synthesis and plating efficiency and a modest effect on cellular growth. One cannot rule out a direct effect of the drugs, but presumably the antiproliferative effects are due to a depletion of nuclear GSH with the subsequent inhibition of the GSH/glutaredoxin-mediated conversion of ribonucleotides to deoxyribonucleotides. However, even after extended treatment, upon drug removal, GSH was rapidly resynthesized and cellular DNA synthesis and growth quickly resumed.     

Glutathione depletion, radiosensitization, and misonidazole potentiation in hypoxic Chinese hamster ovary cells by buthionine sulfoximine

Buthionine sulfoximine (BSO) inhibits the synthesis of glutathione (GSH), the major nonprotein sulfhydryl (NPSH) present in most mammalian cells. BSO concentrations from 1 microM to 0.1 mM reduced intracellular GSH at different rates, while BSO greater than or equal to 0.1 mM (i.e., 0.1 to 2.0 mM), resulting in inhibitor-enzyme saturation, depleted GSH to less than 10% of control within 10 hr at about equal rates. BSO exposures used in these experiments were not cytotoxic with the one exception that 2.0 mM BSO/24 hr reduced cell viability to approximately 50%. However, alterations in either the cell doubling time(s) or the cell age density distribution(s) were not observed with the BSO exposures used to determine its radiosensitizing effect. BSO significantly radiosensitized (ER = 1.41 with 0.1 mM BSO/24 hr) hypoxic, but not aerobic, CHO cells when the GSH and NPSH concentrations were reduced to less than 10 and 20% of control, respectively, and maximum radiosensitivity was even achieved with microM concentrations of BSO (ER = 1.38 with 10 microM BSO/24 hr). Furthermore, BSO exposure (0.1 mM BSO/24 hr) also enhanced the radiosensitizing effect of various concentrations of misonidazole on hypoxic CHO cells.     

The role of thiols in cellular response to radiation and drugs

Cellular nonprotein thiols (NPSH) consist of glutathione (GSH) and other low molecular weight species such as cysteine, cysteamine, and coenzyme A. GSH is usually less than the total cellular NPSH, and with thiol reactive agents, such as diethyl maleate (DEM), its rate of depletion is in part dependent upon the cellular capacity for its resynthesis. If resynthesis is blocked by buthionine-S,R-sulfoximine(BSO), the NPSH, including GSH, is depleted more rapidly, Cellular thiol depletion by diamide, N-ethylmaleimide, and BSO may render oxygenated cells more sensitive to radiation. These cells may or may not show a reduction in the oxygen enhancement ratio (OER). Human A549 lung carcinoma cells depleted of their NPSH either by prolonged culture or by BSO treatment do not show a reduced OER but do show increased aerobic responses to radiation. Some nitroheterocyclic radiosensitizing drugs also deplete cellular thiols under aerobic conditions. Such reactivity may be the reason that they show anomalous radiation sensitization (i.e., better than predicted on the basis of electron affinity). Other nitrocompounds, such as misonidazole, are activated under hypoxic conditions to radical intermediates. When cellular thiols are depleted peroxide is formed. Under hypoxic conditions thiols are depleted because metabolically reduced intermediates react with GSH instead of oxygen. Thiol depletion, under hypoxic conditions, may be the reason that misonidazole and other nitrocompounds show an extra enhancement ratio with hypoxic cells. Thiol depletion by DEM or BSO alters the radiation response of hypoxic cells to misonidazole. In conclusion, we propose an altered thiol model which includes a mechanism for thiol involvement in the aerobic radiation response of cells. This mechanism involves both thiol-linked hydrogen donation to oxygen radical adducts to produce hydroperoxides followed by a GSH peroxidase-catalyzed reduction of the hydroperoxides to intermediates entering into metabolic pathways to produce the original molecule.     

Buthionine sulfoximine induced growth inhibition in human lung carcinoma cells does not correlate with glutathione depletion

Treatment of A549 human lung carcinoma cells with L-buthionine-[S,R]-sulfoximine (BSO) results concomitantly in cellular glutathione (GSH) depletion and growth inhibition. The nature of BSO effects on cell growth and the relationships between BSO inhibition of cell growth and BSO effects on cellular GSH levels were determined in this study. A dose dependent effect of BSO on cell growth was observed, but this effect was found not to correlate with BSO effects on cellular GSH levels. Treatment with BSO for 60 h at concentrations of 5 and 10 mM was found to deplete cellular GSH at similar rates and to an undetectable level (below 0.5 nmol/mg protein). However, cessation of growth occured in 10 mM BSO whereas growth continued at better than one half the control rate in 5 mM BSO. The results suggest there may be a distinct threshold level of intracellular G GSH (on the order of or less than 0.5 nmol/mg protein) required for cell growth and for cells to protect themselves from the antiproliferative effects of BSO. At a concentration of 10 mM, BSO inhibited both DNA and protein synthesis and arrested growth of A549 cells throughout rather than at a specific phase of the cell cycle. BSO inhibition of growth was not, as indicated by colony-forming efficiency (CFE) and electron microscopy studies, accompanied by indications of cytotoxic effects. A stimulatory effect of 0.1 mM BSO on the growth of A549 cells was found also.Abbreviations BSO L-buthionine-[S,R]-sulfoximine - GSH Glutathione (reduced form) - GSSG Glutathione disulfide - DTNB 5,5-dithiobis (2-nitrobenzoate) - PBS Phosphate buffered saline - BSA Bovine serum albumin - PI Propidium iodide - CFE Colony-forming efficiency - EM Electron microscopy     

Effects of glutathione depletion by buthionine sulfoximine on radiosensitization by oxygen and misonidazole in vitro

Buthionine sulfoximine (BSO) has been used to deplete glutathione (GSH) in V79-379A cells in vitro, and the effect on the efficiency of oxygen and misonidazole (MISO) as radiosensitizers has been determined. Treatment with 50 or 500 microM BSO caused a rapid decline in GSH content to less than 5% of control values after 10 hr of exposure (t1/2 = 1.6 hr). Removal of BSO resulted in a rapid regeneration of GSH after 50 microM BSO, but little regeneration was observed over the subsequent 10-hr period after 500 microM. Treatment with either of these two concentrations of BSO for up to 14 hr did not affect cell growth or viability. Cells irradiated in monolayer on glass had an oxygen enhancement ratio (OER) of 3.1. After 10-14 hr pretreatment with 50 microM BSO, washed cells were radiosensitized by GSH depletion at all oxygen tensions tested. The OER was reduced to 2.6, due to greater radiosensitization of hypoxic cells than aerated ones by GSH depletion. GSH depletion had the effect of shifting the enhancement ratio vs pO2 curve to lower oxygen tensions, making oxygen appear more efficient by a factor of approximately 2, based on the pO2 required to give an OER of 2.0. In similar experiments performed with MISO, an enhancement ratio of 2.0 could be achieved with 0.2 mM MISO in anoxic BSO-pretreated cells, compared to 2.7 mM MISO in non-BSO-treated cells. Thus MISO appeared to be more efficient in GSH-depleted cells by a factor of 13.5. These apparent increases in radiosensitizer efficiency in GSH-depleted cells could be explained on the basis of radiosensitization of hypoxic cells by GSH depletion alone (ER = 1.29-1.41). The effect of GSH depletion was approximately equal at all sensitizer concentrations tested, except at high oxygen tensions, where the effect was insignificantly small. These results are consistent with hypoxic cell radiosensitization by GSH depletion and by MISO or oxygen acting by separate mechanisms.     

GSH-dependent regulation of Fas-mediated caspase-8 activation by acrolein

Activation of the cysteine protease caspase-8 by the death receptor Fas (CD95/APO-1) in B lymphoblastoid SKW6.4 cells or Jurkat T cells is associated with GSH depletion. Conversely, GSH depletion by the aldehyde acrolein (3-30 microM) was associated with inhibition of Fas-induced caspase-8 activation, although GSH depletion by buthionine sulfoximine (BSO) did not affect caspase-8 activation. In contrast to BSO, acrolein caused a loss of caspase-8 cysteine content in association with direct alkylation of caspase-8. Our findings indicate that inhibition of caspase-8 by thiol-reactive agents such as acrolein is not due to GSH depletion but caused by direct protein thiol modifications.     

Cellular glutathione depletion by diethyl maleate or buthionine sulfoximine: no effect of glutathione depletion on the oxygen enhancement ratio

The hypoxic and euoxic radiation response for Chinese hamster lung and A549 human lung carcinoma cells was obtained under conditions where their nonprotein thiols, consisting primarily of glutathione (GSH), were depleted by different mechanisms. The GSH conjugating reagent diethylmaleate (DEM) was compared to DL-buthionine-S,R-sulfoximine (BSO), an inhibitor of glutathionine biosynthesis. Each reagent depleted cellular GSH to less than 5% of control values. A 2-hr exposure to 0.5 mM DEM or a 4- or 24-hr exposure to BSO at 10 or 1 mM, respectively, depleted cellular GSH to less than 5% of control values. Both agents sensitized cells irradiated under air or hypoxic conditions. When GSH levels are lowered to less than 5% by both agents, hypoxic DEM-treated cells exhibited slightly greater X-ray sensitization than hypoxic BSO-treated cells. The D0's for hypoxic survival curves were as follows: control, 4.87 Gy; DEM, 3.22 Gy; and BSO, 4.30 Gy for the V79 cells and 5.00 Gy versus 4.02 Gy for BSO-treated A549 cells. The D0's for aerobic V79 cells were 1.70 Gy versus 1.13 Gy, DEM, and 1.43 Gy for BSO-treated cells. The D0's for the aerobic A549 were 1.70 and 1.20 for BSO-treated cells. The aerobic and anoxic sensitization of the cells results in the OER's of 2.8 and 3.0 for the DEM- and BSO-treated cells compared to 2.9 for the V79 control A549. BSO-treated cells showed an OER of 3.3 versus 3 for the control. Our results suggest that GSH depletion by either BSO or DEM sensitizes aerobic cells to radiation but does not appreciably alter the OER.     

Cysteine but not glutathione modulates the radiosensitivity of human melanoma cells by affecting both survival and DNA damage

Glutathione (GSH) and its precursor cysteine (Cys) are both known to react within any cells with oxidative species and thus play an important role in cellular defense mechanisms against oxidative stress. In melanocytes, these are also important precursors of melanogenesis by reacting non-enzymatically with l-dopaquinone to form the sulfur-containing pheomelanin. Our aim was to assess pigment role in the cellular radioprotection mechanism using a human melanoma cell model of mixed-type melanin under GSH depletion to obtain a radiosensitizing effect. The latter has been achieved either by Cys deprivation or GSH specific depletion. We first compared cell survival of Cys-deprived and GSH-depleted cells vs. control cells. Cys deprivation was achieved by decreasing Cys concentration in the culture medium for 24 h. In this condition, no toxicity was observed, Cys and GSH levels decreased, melanogenesis switched to a higher eumelanin synthesis and cells were significantly more resistant to 10-Gy dose of ionizing radiations than untreated cells. Glutathione depletion was achieved with the gamma-glutamylcysteine synthetase inhibitor buthionine-S-sulfoximine (BSO) for 24 h at 50 microM, a concentration yielding no toxicity. In this condition, intracellular GSH level decreased but no change in pigmentation was observed and cells were slightly but significantly more sensitive to radiation than the control. We then compared DNA radio-induced damages by Comet assay in control cells, cells treated as above and cells with stimulated pigmentation by increasing Tyr concentration in the medium. Our results showed that, when intracellular eumelanin content increased, DNA damage decreased. By contrast, DNA damage increased in cells treated with BSO alone. It is concluded that increasing the intracellular eumelanin content by the melanin precursor Tyr or by favoring the Pheo- to Eumelanin switch, compensates for the loss of the two intracellular radioprotectors that are GSH and Cys.     

Cellular recovery of glyceraldehyde-3-phosphate dehydrogenase activity and thiol status after exposure to hydroperoxides

The activity of the thiol-dependent enzyme glyceraldehyde-3-phosphate dehydrogenase (GPD), in vertebrate cells, was modulated by a change in the intracellular thiol:disulfide redox status. Human lung carcinoma cells (A549) were incubated with 1-120 mM H2O2, 1-120 mM t-butyl hydroperoxide, 1-6 mM ethacrynic acid, or 0.1-10 mM N-ethylmaleimide for 5 min. Loss of reduced protein thiols, as measured by binding of the thiol reagent iodoacetic acid to GPD, and loss of GPD enzymatic activity occurred in a dose-dependent manner. Incubation of the cells, following oxidative treatment, in saline for 30 min or with 20 mM dithiothreitol (DTT) partially reversed both changes in GPD. The enzymatic recovery of GPD activity was observed either without addition of thiols to the medium or by incubation of a sonicated cell mixture with 2 mM cysteine, cystine, cysteamine, or glutathione (GSH); GSSG had no effect. Treatment of cells with buthionine sulfoximine (BSO) to decrease cellular GSH by varying amounts caused a dose-related increase in sensitivity of GPD activity to inactivation by H2O2 and decreased cellular ability for subsequent recovery. GPD responded in a similar fashion with oxidative treatment of another lung carcinoma cell line (A427) as well as normal lung tissue from human and rat. These findings indicate that the cellular thiol redox status can be important in determining GPD enzymatic activity.     

Depletion of glutathione after gamma irradiation modifies survival

The relationship between the intracellular glutathione (GSH) concentration and the aerobic radiation response was studied in Chinese hamster ovary cells. Various degrees of GSH depletion were produced by exposure to buthionine sulfoximine (BSO) and/or diethyl maleate (DEM). Diethyl maleate did not act as a classical radiosensitizer under the experimental conditions employed, nor did exposure to DEM/BSO nonspecifically affect protein thiols as measured by thiol blotting. Dose-response curves were obtained using cells irradiated in the absence or presence of DEM/BSO, which decreased GSH levels by 90-95%. Exposure to DEM/BSO did not affect the formation of DNA single-strand breaks or DNA-protein crosslinks measured immediately after irradiation performed at ice temperatures. Analysis of survival curves indicated that the Dq was decreased by 18% when GSH depletion occurred prior to, during, and after irradiation. The DEM/BSO exposure did not affect D0. To study postirradiation conditions, cells were exposed to 10 microM DEM prior to and during irradiation, which was performed at ice temperatures. Levels of GSH were depleted by 75% by this protocol. Immediately after irradiation, the cells were rapidly warmed by the addition of 37 degrees C growth medium containing either 10 or 90 microM DEM. Addition of 10 microM DEM after irradiation did not affect the degree of depletion, which remained constant at 75%. In contrast, GSH depletion was increased to 90% 10 min after addition of the 90 microM DEM. Addition of 90 microM DEM after irradiation produced a statistically significant difference in survival compared to addition of 10 microM DEM. In a second depletion protocol, cells were exposed to 100 microM DEM at room temperature for 5 min, irradiated, incubated at 37 degrees C for 1 h, washed, and then incubated in 50 microM BSO for 24 h. This depletion protocol reduced survival by a factor of 2.6 compared to cells not exposed to the combination of DEM/BSO. Survival was not affected if the cells were exposed to the DEM or BSO alone. This was interpreted to indicate that survival was not affected by GSH depletion occurring after irradiation unless depletion was rapid and sustained. The rate of repair of sublethal and potentially lethal damage was measured and found to be independent of the DEM/BSO exposure. These experimental results in addition to previous ones (Freeman and Meredith, Int. J. Radiat. Oncol. Biol. Phys. 13, 1371-1375, 1987) were interpreted to indicate that under aerobic conditions GSH depletion may alter the expression of radiation damage by affecting metabolic fixation.     

Stimulation of colonic mucosal growth associated with oxidized redox status in rats

Limited data in animal models suggest that colonic mucosa undergoes adaptive growth following massive small bowel resection (SBR). In vitro data suggest that intestinal cell growth is regulated by reactive oxygen species and redox couples [e.g., glutathione (GSH)/glutathione disulfide (GSSG) and cysteine (Cys)/cystine (CySS) redox]. We investigated the effects of SBR and alterations in redox on colonic growth indexes in rats after either small bowel transection (TX) or 80% midjejunoileal resection (RX). Rats were pair fed +/- blockade of endogenous GSH synthesis with buthionine sulfoximine (BSO). Indexes of colonic growth, proliferation, and apoptosis and GSH/GSSG and Cys/CySS redox potentials (E(h)) were determined. RX significantly increased colonic crypt depth, number of cells per crypt, and epithelial cell proliferation [crypt cell bromodeoxyuridine (BrdU) incorporation]. Administration of BSO markedly decreased colonic mucosal GSH, GSSG, and Cys concentrations in both TX and RX groups, with a resultant oxidation of GSH/GSSG and Cys/CySS E(h). BSO did not alter colonic crypt cell apoptosis but significantly increased all colonic mucosal growth indexes (crypt depth, cells/crypt, and BrdU incorporation) in both TX and RX groups in a time- and dose-dependent manner. BSO significantly decreased plasma GSH and GSSG, oxidized GSH/GSSG E(h), and increased plasma Cys and CySS concentrations. Collectively, these data provide in vivo evidence indicating that oxidized colonic mucosal redox status stimulates colonic mucosal growth in rats. The data also suggest that GSH is required to maintain normal colonic and plasma Cys/CySS homeostasis in these animal models.     

Role of glutathione depletion and reactive oxygen species generation in apoptotic signaling in a human B lymphoma cell line

The primary objective of this study was to determine the sequence of biochemical signaling events that occur after modulation of the cellular redox state in the B cell lymphoma line, PW, with emphasis on the role of mitochondrial signaling. L-Buthionine sulphoximine (BSO), which inhibits gamma glutamyl cysteine synthetase (gammaGCS), was used to modulate the cellular redox status. The sequence and role of mitochondrial events and downstream apoptotic signals and mediators was studied. After BSO treatment, there was an early decline in cellular glutathione (GSH), followed by an increase in reactive oxygen species (ROS) production, which induced a variety of apoptotic signals (detectable at different time points) in the absence of any external apoptotic stimuli. The sequence of biochemical events accompanying apoptosis included a 95% decrease in total GSH and a partial (25%) preservation of mitochondrial GSH, without a significant increase in ROS production at 24h. Early activation and nuclear translocation of the nuclear factor kappa B subunit Rel A was observed at approximately 3h after BSO treatment. Cytochrome c release into the cytosol was also seen after 24h of BSO treatment. p53 protein expression was unchanged after redox modulation for up to 72 h, and p21waf1 independent loss of cellular proliferation was observed. Surprisingly, a truncated form of p53 was expressed in a time-dependent manner, beginning at 24h after BSO incubation. Irreversible commitment to apoptosis occurred between 48 and 72 h after BSO treatment when mitochondrial GSH was depleted, and there was an increase in ROS production. Procaspase 3 protein levels showed a time-dependent reduction following incubation with BSO, notably after 48 h, that corresponded with increasing ROS levels. At 96 h, caspase 3 cleavage products were detectable. The pan-caspase inhibitor zVADfmk, partially blocked the induction of apoptosis at 48 h, and was ineffective after 72 h. PW cells could be rescued from apoptosis by removing them from BSO after up to 48, but not 72 h incubation with BSO. Mitochondrial transmembrane potential (DeltaPsi(m)) remained intact in most of the cells during the 72 h observation period, indicating that DeltaPsi(m) dissipation is not an early signal for the induction of redox dependent apoptosis in PW cells. These data suggest that a decrease in GSH alone can act as a potent early activator of apoptotic signaling. Increased ROS production following mitochondrial GSH depletion, represents a crucial event, which irreversibly commits PW cells to apoptosis.     

Apoptosis vs. necrosis: glutathione-mediated cell death during rewarming of rat hepatocytes

Hypothermia induces injury in its own right, but the mechanisms involved in the cell damage are still unclear. The aim of this study was to test the effects that glutathione (GSH) depletion induces on cell death in isolated rat hepatocytes, kept at 4 degrees C for 20 h, by modulating intracellular GSH concentration with diethylmaleate and buthionine sulfoximine (DEM and BSO). Untreated hepatocytes showed Annexin V stained cells (AnxV(+)), scarce propidium iodide stained cells (PI(+)) and presented a low level of lactate dehydrogenase (LDH) leakage after 20 h at 4 degrees C and rewarming at 37 degrees C. When DEM and BSO were added before cold storage, we observed a few AnXV(+) cells and an increase in PI(+) cells associated with LDH release in the incubation medium. Conversely, the addition of DEM and BSO only during rewarming caused a marked increase in cell death by apoptosis. Production of reactive oxygen species (ROS) and thiobarbituric acid species (TBARS), associated with a decrease in GSH concentrations, was higher when DEM and BSO were added before cold storage. Cells treated with DEM and BSO before cold storage showed lower ATP energy stores than hepatocytes treated with DEM and BSO only during rewarming. Pretreatment of hepatocytes with deferoxamine protected against apoptotic and necrotic morphology in conditions of GSH depletion. These results suggest that pretreatment of hepatocytes with DEM and BSO before cold storage induces necrosis, while the treatment of hepatocytes only during rewarming increases apoptosis. In both conditions, iron represents a crucial mediator of cell death.     

The effect of glutathione depletion on sister-chromatid exchange induction by cytostatic drugs

Using sister-chromatid exchanges (SCEs) as an indicator for DNA damage, we investigated the role of glutathione (GSH) as a determinant of cellular sensitivity to the DNA-damaging effects of the cytostatic drugs adriamycin (AM) and cyclophosphamide (CP). Exposure of V79 cells to buthionine sulfoximine (BSO) resulted in a complete depletion of cellular GSH content without toxicity and without increasing the SCE frequency. Subsequent 3-h treatment of GSH-depleted cells with AM or S9-mix-activated CP caused a potentiation of SCE induction. In Chinese hamster ovary (CHO) cells, which showed a higher GSH level compared to V79 cells, BSO treatment led to a depletion of GSH to about 5% of the control and increased SCE induction by AM and CP. Compared to V79 cells, the effect of AM on SCE frequencies was less distinct in CHO cells, while CP exerted a similar effect in both cell lines. Pretreatment of V79 cells with GSH increased the cellular GSH content, but had no effect on the induction of SCEs by AM, and pretreatment with cysteine influenced neither GSH levels nor SCE induction by AM. The study shows that SCEs are a suitable indicator for testing the modulation of of drug genotoxicity by GSH. The importance of different GSH contents of cell lines for their response to mutagens is discussed.