vitamin-k-semiquinone-radical and diethyl-maleate

The bZip transcription factor Yap1p plays an important role in oxidative stress response and multidrug resistance in Saccharomyces cerevisiae. We have previously demonstrated that the FLR1 gene, encoding a multidrug transporter of the major facilitator superfamily, is a transcriptional target of Yap1p. The FLR1 promoter contains three potential Yap1p response elements (YREs) at positions -148 (YRE1), -167 (YRE2), and -364 (YRE3). To address the function of these YREs, the three sites have been individually mutated and tested in transactivation assays. Our results show that (i) each of the three YREs is functional and important for the optimal transactivation of FLR1 by Yap1p and that (ii) the three YREs are not functionally equivalent, mutation of YRE3 being the most deleterious, followed by YRE2 and YRE1. Simultaneous mutation of the three YREs abolished transactivation of the promoter by Yap1p, demonstrating that the three sites are essential for the regulation of FLR1 by Yap1p. Gel retardation assays confirmed that Yap1p differentially binds to the three YREs (YRE3 > YRE2 > YRE1). We show that the transcription of FLR1 is induced upon cell treatment with the oxidizing agents diamide, diethylmaleate, hydrogen peroxide, and tert-butyl hydroperoxide, the antimitotic drug benomyl, and the alkylating agent methylmethane sulfonate and that this induction is mediated by Yap1p through the three YREs. Finally, we show that FLR1 overexpression confers resistance to diamide, diethylmaleate, and menadione but hypersensitivity to H(2)O(2), demonstrating that the Flr1p transporter participates in Yap1p-mediated oxidative stress response in S. cerevisiae.

Topics: Base Sequence; Binding Sites; Carrier Proteins; Diamide; DNA Primers; DNA-Binding Proteins; Fungal Proteins; Gene Expression Regulation, Fungal; Hydrogen Peroxide; Kinetics; Maleates; Membrane Transport Proteins; Molecular Sequence Data; Mutagenesis, Site-Directed; Organic Anion Transporters; Promoter Regions, Genetic; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins; Sequence Deletion; Transcription Factors; Transcriptional Activation; Vitamin K

Reduced glutathione (GSH) is considered to play a central role in protection of cells from oxidant injury. However, the question remains as to whether sustained elevation of intracellular GSH levels, as compared with the ability to rapidly upregulate GSH synthesis, is more important with respect to protection of cell constituents from oxidative stress. To address this question, we conducted studies to evaluate the direct influence of chronically increased endogenous GSH content on chemically induced intracellular free radical formation and oxidative stress using a kidney epithelial cell model adapted to sustain intracellular GSH concentrations in excess of eightfold that observed in unadapted parent kidney cells. Elevated GSH levels in adapted cells were found to be attributable, at least in part, to coordinately increased amounts of both the regulatory and catalytic subunits of gamma-glutamylcysteine synthetase (GCS), the rate-limiting enzyme in GSH synthesis. Studies using electron spin resonance (ESR) spectroscopy and scanning laser cytometry demonstrated that cells having sustained elevation of GSH levels did not attenuate free radical formation and associated oxidative stress compared with parent cells when treated with the prooxidant chemicals, menadione or potassium dichromate. In contrast, nonadapted kidney parent cells treated 18 h after initial prooxidant challenge displayed significantly attenuated free radical signals. Additionally, cells adapted to sustain excess GSH were somewhat more sensitive than parent cells in terms of resistance to prooxidant (chromate) toxicity, as determined by cell viability assays. These findings suggest that the capacity of cells to rapidly upregulate GSH synthesis, rather the ability to chronically sustain elevated intracellular GSH levels, may play a more important role in terms of protection from cytotoxicity associated with prooxidant chemical exposures.

Topics: Adaptation, Physiological; Animals; Blotting, Northern; Cell Line; Cell Separation; Cell Survival; Electron Spin Resonance Spectroscopy; Epithelial Cells; Flow Cytometry; Free Radicals; Glutamate-Cysteine Ligase; Glutathione; Kidney; Maleates; Oxidative Stress; Potassium Dichromate; Rats; RNA, Messenger; Spin Trapping; Up-Regulation; Vitamin K

The protein, NKEF (natural killer enhancing factor), has been identified as a member of an antioxidant family of proteins capable of protecting against protein oxidation in cell-free assay systems. The mechanism of action for this family of proteins appears to involve scavenging or suppressing formation of protein thiyl radicals. In the present study we investigated the antioxidant protective properties of the NKEF-B protein overexpressed in an endothelial cell line (ECV304). Nkef-B-transfected cells displayed significantly lower levels of reactive oxygen species (ROS) compared with control or vector-transfected cells. Tert-Butylhydroperoxide-induced ROS was 15% lower in nkef-B-transfected cells and cytotoxicity was slightly, though not significantly, lower. NKEF-B had no effect on ROS induced by menadione or xanthine plus xanthine oxidase. NKEF-B overexpression resulted in slightly (approximately 10%) lower levels of cellular glutathione (GSH) and had no effect on rate or extent of GSH depletion following either diethylmaleate (DEM) or buthionine sulfoximine (BSO) treatment. Lipid peroxidation, assessed as thiobarbituric acid-reactive substances, was 40% lower in nkef-B-transfected cells compared with vector-only-transfected cells. DEM-induced lipid peroxidation was suppressed by NKEF-B at DEM concentrations of 20 microM to 1 mM. At 10 mM DEM, lipid peroxidation was unaffected by NKEF-B. NKEF-B expression also protected cells against menadione-induced inhibition of [3H]-thymidine uptake. The NKEF-B protein appears most effective in suppressing basal low-level oxidative injury such as that produced during normal metabolism. These results indicate that overexpression of the NKEF-B protein promotes resistance to oxidative stress in this endothelial cell line.

Topics: Antioxidants; Blood Proteins; Cell Death; Cell Line; Dose-Response Relationship, Drug; Epithelial Cells; Epithelium; Fluoresceins; Glutathione; Heat-Shock Proteins; Humans; Maleates; Peroxidases; Peroxides; Peroxiredoxins; Reactive Oxygen Species; tert-Butylhydroperoxide; Thiobarbituric Acid Reactive Substances; Toxins, Biological; Transfection; Vitamin K

The neuroprotective action of insulin-like growth factor I (IGF-I) was tested in immortalized hypothalamic GT1-7 cells exposed to reduced glutathione depleting agents, which cause oxidative stress and cell death. The extent of cell survival was assessed by either using the 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide cytotoxicity assay or counting at the fluorescence microscope GT1-7 cells prelabeled with fluorescent dyes selective for viable and dead cells. Treatments with buthionine sulfoximine (500 microns), diethylmaleate (1 mM), and ethacrynic acid (200 microns) caused diffuse GT1-7 cell death (40-60%). Exposure of the same cells to IGF-I (either before or concomitant to the toxic agent, depending on the drug used) significantly prevented neuronal death. This effect was rapid, concentration-dependent, maximal at concentrations of 25-50 ng/ml, and mimicked by IGF-II, fibroblast growth factor, and the potent antioxidant idebenone. In contrast, IGF-I, as well as idebenone, were completely ineffective in antagonizing the toxic effect produced by different concentrations of menadione. In conclusion, the present data demonstrate a protective role for IGF-I against glutathione depleting agents-induced damage in GT1-7 cells suggesting an antioxidant action of this growth factor in hypothalamic neurons.

Topics: Animals; Benzoquinones; Buthionine Sulfoximine; Cell Death; Cell Line, Transformed; Ethacrynic Acid; Hypothalamus; Insulin-Like Growth Factor I; Maleates; Methionine Sulfoximine; Mice; Mice, Transgenic; Neurons; Neuroprotective Agents; Radiation-Protective Agents; Ubiquinone; Vitamin K

1. The ability of ascorbic acid to protect from prooxidant-induced toxic injury was investigated in isolated, intact rat hepatocytes, whose ascorbic acid content had been restored by means of exogenous supplementation. 2. Ascorbate-supplemented and ascorbate-non-supplemented cells in suspension were treated with a series of different prooxidants (allyl alcohol, diethyl maleate, carbon tetrachloride, menadione), and the development of lipid peroxidation and cell injury was evaluated. 3. With allyl alcohol and diethyl maleate, ascorbic acid was able to protect cells from both lipid peroxidation and cell injury. The same protection was offered by ascorbate also in hepatocytes obtained from vitamin E-deficient animals. 4. With carbon tetrachloride, ascorbate supplementation did not affect the initial steps of lipid peroxidation, but nevertheless provided a marked protection against lipid peroxidation and cell injury at later times of incubation. The protection was unaffected by the vitamin E content of cells. 5. With menadione, a toxin which does not induce lipid peroxidation, ascorbic acid did not protect cells against injury. 6. It is concluded that ascorbic acid can act as an efficient antioxidant in isolated rat liver cells, with protection against cell injury. The antioxidant effect appears primarily to involve membrane lipids, and can be independent from the cellular content of vitamin E, thus suggesting that ascorbic acid can play a direct and independent role in the intact cell, in addition to its synergistic interaction with vitamin E described in other models.

Topics: 1-Propanol; Animals; Antioxidants; Ascorbic Acid; Carbon Tetrachloride; Cell Survival; Glutathione; Lipid Peroxidation; Liver; Male; Maleates; Malondialdehyde; Propanols; Rats; Rats, Sprague-Dawley; Vitamin E; Vitamin K

The synthesis of 23 kDa protein was enhanced when mouse peritoneal macrophages were exposed to oxidative agents such as hydrogen peroxide and menadione, or to sulfhydryl-reactive agents such as diethylmaleate, cadmium chloride and sodium arsenite. After 11 h exposure to these agents the 23 kDa protein was one of the actively synthesized proteins in the macrophages. Under similar conditions the 34 kDa protein previously identified as heme oxygenase, was induced and its synthesis preceded that of the 23 kDa protein. Neither the 23 kDa or the 34 kDa protein was induced by hyperthermia. Conversely, the various oxidative and sulfhydryl-reactive agents employed here did not induce the major heat shock proteins in the macrophages. When the macrophages were activated by bacterial lipopolysaccharide or other stimulants, many proteins are known to be induced, however, the 23 kDa and 34 kDa proteins were not induced. The 34 kDa protein, i.e., heme oxygenase, has been found to be stress-induced in various types of cell, but not the 23 kDa protein. This suggests that the 23 kDa protein is a stress protein predominantly expressed in macrophages.

Topics: Animals; Cadmium; Cadmium Chloride; Chlorides; Female; Heat-Shock Proteins; Heme Oxygenase (Decyclizing); Hydrogen Peroxide; Lipopolysaccharides; Macrophages; Maleates; Mice; Mice, Inbred C57BL; Peritoneal Cavity; Protein Biosynthesis; Vitamin K

The intracellular distribution of glutathione (GSH) in cultured hepatocytes has been investigated by using the compound monochlorobimane (BmCl), which interacts specifically with GSH to form a highly fluorescent adduct. Image analysis of BmCl-labeled hepatocytes predominantly localized the fluorescence in the nucleus; the nuclear/cytoplasmic concentration gradient was approximately three. This concentration gradient was collapsed by treatment of the cells with ATP-depleting agents. The uneven distribution of BmCl fluorescence was not attributable to (i) nonspecific interaction of BmCl with protein sulfhydryl groups, (ii) any selective nuclear localization of the GSH transferase(s) catalyzing formation of the GSH-BmCl conjugate, or (iii) any apparent alterations in cell morphology from culture conditions, suggesting that this distribution did, indeed, reflect a nuclear compartmentalization of GSH. That the nuclear pool of GSH was found more resistant to depletion by several agents than the cytoplasmic pool supports the assumption that GSH is essential in protecting DNA and other nuclear structures from chemical injury.

Topics: Animals; Bridged Bicyclo Compounds; Buthionine Sulfoximine; Carbonyl Cyanide m-Chlorophenyl Hydrazone; Cell Nucleus; Cells, Cultured; Cytosol; Ethylmaleimide; Fluorescein-5-isothiocyanate; Fluorescent Dyes; Glutathione; Kinetics; Liver; Male; Maleates; Methionine Sulfoximine; Pyrazoles; Rats; Rats, Inbred Strains; Spectrometry, Fluorescence; Subcellular Fractions; Vitamin K

Metallothionein (MT) is a low-molecular-weight protein with a high cysteine content that has been proposed to play a role in protecting against oxidative stress. For example, MT has been shown to be a scavenger of hydroxyl radicals in vitro, and cells with high levels of MT are resistant to radiation. However, it is not known if compounds that cause oxidative stress affect MT levels. Therefore, mice were injected subcutaneously with 11 chemicals (t-butyl hydroperoxide, paraquat, diquat, menadione, metronidazole, adriamycin, 3-methylindole, cisplatin, diamide, diethyl maleate, and phorone) that produce oxidative stress by four main mechanisms. MT was quantitated in the cytosol of major organs (liver, pancreas, spleen, kidney, intestine, heart, and lung) by the Cd/hemoglobin radioassay 24 hr after administration of the chemicals. All agents significantly increased MT levels in at least one organ. Liver was the most responsive to these agents in that all 11 chemicals increased MT concentrations in liver, with diethyl maleate, paraquat, and diamide producing 20- to 30-fold increases. Pancreas and kidney were the next most responsive organs to these chemicals. The organ least responsive to these agents was the heart, as only 3 compounds caused significant increases in MT concentrations in heart. Diethyl maleate and diquat were the most general inducers of MT in that they increased MT in six of the seven organs examined. No treatment resulted in a significant decrease in MT concentration in any organ. In conclusion, chemicals that produce oxidative stress by one of four distinct mechanisms are very effective at increasing MT concentrations in a variety of organs. This suggests that MT might be involved in protecting against oxidative stress.

Topics: Animals; Cisplatin; Cytosol; Diamide; Diquat; Doxorubicin; Ketones; Liver; Male; Maleates; Metallothionein; Metronidazole; Mice; Mice, Inbred Strains; Organ Specificity; Paraquat; Peroxides; Skatole; tert-Butylhydroperoxide; Vitamin K

The aim of this study has been to define cytotoxic mechanisms that may cause clonal expansion in the liver of pre-carcinogenic cells. An in vitro model, which has been described previously, was used. Hepatocytes were isolated from carcinogen-treated rats and a high proportion of the cells were gamma-glutamyltranspeptidase (GGT)-positive. The cells were incubated in suspension and exposed to toxic agents in concentrations that induced a moderate increase in cellular leakage within 3 h. Samples were withdrawn and sampled cells were then allowed to attach to collagen-coated plates. Attached cells were stained and the ratio of GGT-positive/GGT-negative cells (GGT-ratio) was determined. The initial GGT-ratio was 10.4 +/- 4.7% and an increased ratio was taken as a sign of toxicity that resulted in a selection of GGT-positive cells. In a first series of experiments it was shown that hydroquinone and menadione increase the GGT-ratio, while diquat, sodium selenite, diethyl maleate or phorone do not. However, diethyl maleate in combination with diquat increased the GGT-ratio. Hydrogen peroxide (5 mM) increased the GGT-ratio as effectively as hydroquinone (0.3 mM). Lower concentrations of H2O2 (0.05 mM) increased the GGT-ratio in GSH-depleted cells. The changes induced by hydroquinone and H2O2 in low concentration were reversible. In another series of experiments, plates coated with antibodies against beta 1-integrin were used. An increase in the GGT-ratio was obtained with anti beta 1-integrin, but not with broad spectrum anti-rat hepatocyte or anti-rat beta 2-microglobulin antibodies as substrata. These data suggested an involvement of the beta 1-integrin in the selection. Taken together, these data indicate that GGT-positive hepatocytes are protected against GSH depletion and oxidative stress that may result in reversible receptor alterations.

Topics: Animals; Biomarkers, Tumor; Cell Transformation, Neoplastic; Cells, Cultured; Collagen; Diethylnitrosamine; Diquat; Female; gamma-Glutamyltransferase; Glutathione; Hydrogen Peroxide; Hydroquinones; Ketones; Kinetics; Liver; Maleates; Phenobarbital; Rats; Receptors, Cell Surface; Receptors, Collagen; Selenium; Sodium Selenite; Vitamin K

Isolated hepatocytes were prepared from fed and fasted rats and exposed to a range of menadione (2-methyl-1,4-naphthoquinone) concentrations. Menadione (300 microM) caused a rapid decline in the (NADPH)/(NADPH + NADP+) ratio from 0.85 to 0.39 within 15 min, with further decreases over the 90-min incubation period in cells isolated from fed animals. This decrease of NADPH resulted from oxidation to NADP+ since there was no loss of total pyridine nucleotide (NADP+ + NADPH) content. In addition, menadione (100 microM) caused a five-fold stimulation of the hexose monophosphate shunt by 30 min as indicated by the oxidation of [1-14C]glucose. LDH leakage was slightly but significantly elevated (30% of total) following exposure of cells to 300 microM menadione for 2 hr. Menadione caused a concentration-dependent GSH depletion: 100 microM menadione caused no depletion and 200 and 300 microM menadione caused a 75 and 95% decrease, respectively. Intracellular NADPH was significantly reduced within 30 min by 100 and 200 microM menadione but then returned to values equivalent to or greater than control by 60 min. In contrast, a sustained decrease of NADPH was produced by 300 microM menadione (5% of control after 2 hr). A marked potentiation of the oxidative cell injury produced by menadione was observed in hepatocytes prepared from 24-hr-fasted rats. LDH leakage was 50 and 95% when these cells were exposed to 100 and 200 microM menadione, respectively. Menadione (100 and 200 microM) also caused a marked GSH depletion (95% of control) by 90 min. In contrast to cells isolated from fed animals, menadione (100 and 200 microM) caused an 85% depletion of NADPH by 60 min in cells isolated from fasted rats. This potentiation of menadione-induced oxidative injury was not related to the decreased GSH content produced by fasting since menadione toxicity was not potentiated in control cells partially depleted of GSH by diethyl maleate. A further comparison was made between cells isolated from fasted rats and incubated either with or without supplemental glucose in order to determine a possible protective effect by glucose. In this comparison a significant (p less than 0.05) glucose effect was indeed observed in the direction of preventing GSH and NADPH depletion, as well as attenuating LDH leakage, when hepatocytes were exposed to either 50 or 100 microM menadione.(ABSTRACT TRUNCATED AT 400 WORDS)

Topics: Animals; Drug Synergism; Fasting; Food; Glucose; Glutathione; L-Lactate Dehydrogenase; Liver; Male; Maleates; NADP; Oxidation-Reduction; Pentose Phosphate Pathway; Rats; Rats, Inbred Strains; Vitamin K

The toxicological implications of alterations in intracellular thiol homeostasis during menadione metabolism have been investigated using freshly isolated rat hepatocytes. A strict correlation between depletion of protein sulfhydryl groups and loss of cell viability was observed. Loss of protein thiols preceded cell death, and occurred more rapidly in cells with decreased levels of reduced glutathione. Depletion of protein thiols was also associated with inhibition of Ca2+ efflux from the cells and perturbation of intracellular Ca2+ homeostasis. It is proposed that the oxidative stress induced by menadione metabolism in isolated hepatocytes results in the depletion of both soluble and protein thiols, and that the latter effect is critically associated with a perturbation of Ca2+ homeostasis and loss of cell viability.

Topics: Animals; Calcium; Cell Survival; Homeostasis; In Vitro Techniques; Ion Channels; Liver; Male; Maleates; Oxidation-Reduction; Proteins; Rats; Rats, Inbred Strains; Sulfhydryl Compounds; Vitamin K