Effect of ethanol on glutathione concentration in isolated hepatocytes.

1. Ethanol induces a decrease in GSH (reduced glutathione) concentration is isolated hepatocytes. Maximal effects appear at 20 mM-ethanol. The concentration-dependence of this decrease is paralleled by the concentration-dependence of the activity of alcohol dehydrogenase. 2. Pyrazole, a specific inhibitor of alcohol dehydrogenase, prevents the ethanol-induced GSH depletion. 3. Acetaldehyde, above 0.05 mM, also promotes a decrease in GSH concentration in hepatocytes. 4. Disulfiram (0.05 mM), an inhibitor of aldehyde dehydrogenase, potentiates the fall in GSH concentration caused by acetaldehyde. 5. The findings support the hypothesis that acetaldehyde is responsible for the depletion of GSH induced by ethanol. 6. Methionine prevents the effect of alcohol or acetaldehyde on GSH concentration in hepatocytes.     

Effect of methylglyoxal on glucose formation, drug oxidation and glutathione content in isolated murine hepatocytes

The first stage in the formation of glucose from acetone involves two oxidation steps catalyzed by isozymes of the cytochrome P-450 II E1 gene subfamily; methylglyoxal formed this way is further converted to pyruvate by a reversible conjugation with reduced glutathione. The effect of methylglyoxal on glucose formation, oxidation of aminopyrine, aniline and on reduced glutathione content was investigated in isolated hepatocytes prepared from (i) fasted or (ii) fasted and acetone (known to induce isozymes of P-450 II E1 gene subfamily) pretreated mice. Glucose formation and drug oxidation were increased by methylglyoxal at concentrations below 1 mM, but were severely decreased above 1 mM. Methylglyoxal also decreased protein synthesis at concentrations above 1 mM. If the addition of methylglyoxal was combined with that of other gluconeogenic precursors and glucose the initial increasing effect on drug oxidation was moderated or diminished and the decreasing effect (at high concentrations) was enhanced. The glutathione content of the cells was decreased by methylglyoxal in a concentration dependent manner. Acetone pretreatment of mice also resulted in a decreased glutathione content of the liver. Based on these observations it is assumed that methylglyoxal has contrasting effects in hepatocytes, and can contribute to the disturbed metabolism under circumstances when the acetone production is elevated.     

Mitochondrial poisons cause depletion of reduced glutathione in isolated hepatocytes.

Antimycin A, KCN, and 1-methyl-4-phenylpyridinium ion (MPP+) all produced a marked depletion of cellular GSH levels in freshly isolated hepatocytes. This effect was consistently observed before the onset of cytotoxicity and seemed to be correlated with the loss of cellular ATP induced by these mitochondrial poisons. Concentrations of GSSG remained unchanged both intracellularly and extracellularly, indicating that oxidation was not involved in the events leading to GSH depletion. Approximately 40% of the decrease of intracellular GSH was accounted for by efflux of this tripeptide, assessed by increased formation of cysteinyl-glutathione when hepatocytes were incubated in the presence of 0.2 mM cystine. Therefore, an overall loss of glutathione was observed during incubations with all three inhibitors of mitochondrial function. Addition of 10 mM fructose to the incubation media substantially protected against GSH depletion caused by antimycin A, KCN, and MPP+. These results indicate that energy-dependent mechanisms are involved in the maintenance of intracellular GSH levels, and suggest that GSH depletion may be a general phenomenon associated with impairment of mitochondrial function.     

Cellular glutathione content and K values

The K values for two cell strains with differing intrinsic GSH concentrations have been measured with the yield of DNA breaks as end-point of the radiation effect. The K value of the strain with reduced GSH content was decreased (1.59 microM O2) in comparison to the K value (3.01 microM O2) for the strain with a normal GSH content. The significance of the observation is discussed in relation to competition models. All variants of the competition model agree in predicting a reduction of K, if GSH is reduced.     

Postischemic injury in isolated rat hearts is not aggravated by prior depletion of myocardial glutathione

The aim of this study was to test the hypothesis that a decreased myocardial concentration of reduced glutathione (GSH) during ischemia renders the myocardium more susceptible to injury by reactive oxygen species generated during early reperfusion. To this end, rats were pretreated with L-buthionine-S,R-sulfoximine (2 mmol/kg), which depleted myocardial GSH by 55%. Isolated buffer-perfused hearts were subjected to 30 min of either hypothermic or normothermic no-flow ischemia followed by reperfusion. Prior depletion of myocardial GSH did not lead to oxidative stress during reperfusion, as myocardial concentration of glutathione disulfide (GSSG) was not increased after 5 and 30 min of reperfusion. In addition, prior depletion of GSH did not exacerbate myocardial enzyme release, nor did it impair the recoveries of tissue ATP, coronary flow rate and left ventricular developed pressure during reperfusion after either hypothermic or normothermic ischemia. Even administration of the prooxidant cumene hydroperoxide (20 M) to postischemic GSH-depleted hearts during the first 10 min of reperfusion did not aggravate postischemic injury, although this prooxidant load induced oxidative stress, as indicated by an increased myocardial concentration of GSSG. These results do not support the hypothesis that a reduced myocardial concentration of GSH during ischemia increases the susceptibility to injury mediated by reactive oxygen species generated during reperfusion. Apparently, myocardial tissue possesses a large excess of GSH compared to the quantity of reactive oxygen species generated upon reperfusion. (Mol Cell Biochem 156: 79-85, 1996)     

Reduction of intracellular glutathione content and radiosensitivity

The intracellular glutathione (GSH) content of HeLa, CHO and V79 cells was reduced by incubating the cells in growth medium containing buthionine sulphoximine or diethyl maleate (DEM). Clonogenicity, single-strand DNA breaks (ssb) and double-strand DNA breaks (dsb) were used as criteria for radiation-induced damage after X- or gamma-irradiation. In survival experiments, DEM gave a slightly larger sensitization although it gave a smaller reduction of the intracellular GSH. In general, sensitization was larger for dsb than for ssb, also the reduction of the o.e.r. was generally larger for dsb than for ssb. This may be due to the higher dose rate in case of dsb experiments resulting in a higher rate of radiochemical oxygen consumption. In general, no effect was found on post-irradiation repair of ssb and dsb.     

Glutathione conjugation by isolated lung cells and the isolated, perfused lung. Effect of extracellular glutathione

Cells isolated from rat lung by protease digestion were found to catalyze the reduced glutathione (GSH) conjugation of 1-chloro-2,4-dinitrobenzene. The rate of conjugation was stimulated severalfold in the presence of GSH, indicating uptake and utilization of extracellular GSH by the lung cells. The stimulation was dependent on the GSH concentration and not due to a spontaneous nonenzymatic reaction or to extracellular GSH-transferase activity. Conjugation of 1-chloro-2,4-dinitrobenzene was also measured using isolated perfused rat lung. The conjugation, which was linear for a longer time than with the isolated cells, was also stimulated in the presence of GSH in the perfusion medium. The results indicate the ability of rat lung to utilize extracellular GSH.     

Intracellular adaptations of glutathione content in Cucurbita pepo L. induced by treatment with reduced glutathione and buthionine sulfoximine

The intracellular effects of GSH (reduced glutathione) and BSO (buthionine sulfoximine) treatment on glutathione content were investigated with immunogold labeling in individual cellular compartments of Cucurbita pepo L. seedlings. Generally, GSH treatment led to increased levels of glutathione in roots and leaves (up to 3.5-fold in nuclei), whereas BSO treatment significantly decreased glutathione content in all organs. Transmission electron microscopy revealed that glutathione levels in mitochondria, which showed the highest glutathione labeling density of all compartments, remained generally unaffected by both treatments. Since glutathione within mitochondria is involved in the regulation of cell death, these results indicate that high and stable levels of glutathione in mitochondria play an important role in cell survival strategies. BSO treatment significantly decreased glutathione levels (1) in roots by about 78% in plastids and 60.8% in the cytosol and (2) in cotyledons by about 55% in the cytosol and 38.6% in plastids. After a short recovery period, glutathione levels were significantly increased in plastids and the cytosol of root tip cells (up to 3.7-fold) and back to control values in cotyledons. These results indicate that plastids, either alone or together with the cytosol, are the main center of glutathione synthesis in leaves as well as in roots. After GSH treatment for 24 h, severe ultrastructural damage related to increased levels of glutathione was found in roots, in all organelles except mitochondria. Possible negative effects of GSH treatment leading to the observed ultrastructural damage are discussed.     

Glutathione S-transferases of the bovine retina. Evidence that glutathione peroxidase activity is the result of glutathione S-transferase.

We have purified two isoenzymes of glutathione S-transferase from bovine retina to apparent homogeneity through a combination of gel-filtration chromatography, affinity chromatography and isoelectric focusing. The more anionic (pI = 6.34) and less anionic (pI = 6.87) isoenzymes were comparable with respect to kinetic and structural parameters. The Km for both substrates, reduced glutathione and 1-chloro-2,4-dinitrobenzene, bilirubin inhibition of glutathione conjugation to 1-chloro-2,4-dinitrobenzene, 1-chloro-2,4-dinitrobenzene inactivation of enzyme activity and molecular weight were similar. However, pH optimum and energy of activation were found to differ considerably. Retina was found to have no selenium-dependent glutathione peroxidase activity. The total glutathione peroxidase activity fractionated with the transferases in the gel-filtration range of mol.wt. 49000 and expressed activity with only organic hydroperoxides as substrate. Only the more anionic isoenzyme expressed both transferase and peroxidase activity.     

Reduced glutathione content in human sperm is decreased after cryopreservation: Effect of the addition of reduced glutathione to the freezing and thawing extenders

In this study, total glutathione content was determined in human spermatozoa before and after cryopreservation. Total GSH in fresh semen was 4.47 ± 0.46 nmol/10⁸ cells. Following semen cryopreservation, GSH decreased to 1.62 ± 0.13 nmol/10⁸ cells, a 64% reduction (p < 0.01). This decrease in GSH content was associated with a decrease in sperm progressive motility (68% of reduction, p < 0.01). Addition of 1 mM GSH to the freezing extender increased the percentage of total motility and sperm viability. It also modified the motility pattern measured by CASA with changes in the straight-line and average path velocities and wobble of the curvilinear trajectory. Addition of GSH to the freezing media reduced spermatozoa ROS levels and increased the level of sulfhydryl groups on membrane proteins. Nevertheless, no effect of GSH addition on lipid membrane disorder or chromatin condensation was detected. Addition of 1 or 5 mM GSH to the thawing media increased the percentage of motile and progressively motile spermatozoa, but no effect on viability was detected. In conclusion, the antioxidant defensive capacity of the GSH is severely altered by the freeze–thawing process. The addition of GSH to the freezing and thawing extender could be of partial and limited benefit in improving the function of frozen human spermatozoa.     

Flow cytometric monitoring of glutathione content and anthracycline retention in tumor cells.

We have used an enzymatic (spectro-photometric) and a flow cytometric (GSH-MBCL) method to compare the glutathione (GSH) content of doxorubicin sensitive (P388) and resistant (P388/R-84) murine leukemic and human lung cancer cells. The flow cytometric analysis revealed that GSH-MBCL conjugate formation was dependent on glutathione-S-transferase (GST) activity. The human solid tumor cell lines exhibited extensive heterogeneity, high GSH content, and GST activity. In contrast to the enzymatic method, the flow cytometric method did not accurately reflect the 95% reduction in GSH content of cells treated for 24 h with 100 microM BSO. Possible reaction of MBCL with other sulfhydryl groups (other than GSH) in BSO-treated cells may be responsible for this discordance. We have also shown the feasibility of using dual parameter flow cytometry to monitor cellular anthracycline (daunorubicin) retention and GSH-MBCL conjugate fluorescence in human tumor cells. These two parameters, which measure drug retention and cellular detoxification, are believed to be the important determinants of chemoresistance in tumor cells.     

Properties of glutathione peroxidase isolated from human plasma

Human plasma glutathione peroxidase (GPx) was purified to homogeneity by ammonium sulfate fractionation, gel filtration on Sephadex G-150, chromatography on DEAE Sephacel, chromatofocusing with polybuffer, and gel filtration with Sephadex G-75. This isolation resulted in about 5,400-fold purification of the enzyme with a 32% yield in enzyme activity. The final preparation had a specific activity of about 28 units (mmoles NADPH oxidized) per milligram of protein. Determination of selenium on the purified enzyme revealed a content of 3.8 g atoms per mole GPx. Gel electrophoresis using SDS with standard proteins revealed a molecular weight of about 23,000 for the subunits, which would indicate a molecular weight of about 92,000 for the native enzyme. Amino acid analyses of the purified GPx indicated aspartate, glutamate, proline, glycine, alanine, and leucine as the predominant amino acids and cysteine, methionine, tryptophan, and histidine as the minor amino acids.     

The hepatic glutathione content and glutathione S-transferase activity in the pike (Esox lucius L.) and rat.

1. The content of glutathione and glutathione disulfide and the activity of the glutathione S-transferase were determined in the liver of pike and rat. 2. It was found that the liver of pike contains far less glutathione than the liver of rats, while the glutathione disulfide content was similar in both species. 3. The activity of the hepatic glutathione S-transferase was more effective in pike than in rats.     

Taurine content of isolated rat alveolar type I cells.

1. Rat alveolar type I cells were isolated by enzymatic digestion and purified by centrifugal elutriation and specific surface adsorption. 2. The identity of the harvested cells was confirmed using electronic cell sizing and transmission electron microscopy. 3. Purified cell preparations contained 4.6 +/- 2.3 x 10(6) type I cells/rat lung with a purity of 79 +/- 3%. 4. Isolated type I cells exhibited the following characteristics: mean cell volume = 716 +/- 48 microns 3; diameter = 11.1 +/- 0.7 microns; and cell water content = 0.50 +/- 0.03 microliter/10(6) cells. 5. Taurine content of these alveolar type I cells was measured by HPLC. 6. The intracellular taurine concentration of type I cells was 0.14 +/- 0.07 mM, a value close to that of plasma (0.1 mM).