UMLS:C1260386 - FACTA Search

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Query: UMLS:C1260386 (GSH)
38,102 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

NAD(P)H acts as a two-electron reductant in physiological, enzyme-controlled processes. Under nonenzymatic conditions, a couple of one-electron oxidants easily oxidize NADH to the NAD(.) radical. This radical reduces molecular oxygen to the superoxide radical (O-(2)) at a near to the diffusion-controlled rate, thereby subsequently forming hydrogen peroxide (H(2)O(2)). Because peroxynitrite can act as a one-electron oxidant, the reaction of NAD(P)H with both authentic peroxynitrite and the nitric oxide ((. )NO) and O-(2) releasing compound 3-morpholinosydnonimine N-ethylcarbamide (SIN-1) was studied. Authentic peroxynitrite oxidized NADH with an efficiency of approximately 25 and 8% in the absence and presence of bicarbonate/carbon dioxide (HCO(3)(-)/CO(2)), respectively. NADH reacted 5-100 times faster with peroxynitrite than do the known peroxynitrite scavengers glutathione, cysteine, and tryptophan. Furthermore, NADH was found to be highly effective in suppressing peroxynitrite-mediated nitration reactions even in the presence of HCO(3)(-)/CO(2). Reaction of NADH with authentic peroxynitrite resulted in the formation of NAD(+) and O-(2) and, thus, of H(2)O(2) with yields of about 3 and 10% relative to the added amounts of peroxynitrite and NADH, respectively. Peroxynitrite generated in situ from SIN-1 gave virtually the same results; however, two remarkable exceptions were recognized. First, the efficiency of NADH oxidation increased to 60-90% regardless of the presence of HCO(3)(-)/CO(2), along with an increase of H(2)O(2) formation to about 23 and 35% relative to the amounts of added SIN-1 and NADH. Second, and more interesting, the peroxynitrite scavenger glutathione (GSH) was needed in a 75-fold surplus to inhibit the SIN-1-dependent oxidation of NADH half-maximal in the presence of HCO(3)(-)/CO(2). Similar results were obtained with NADPH. Hence, peroxynitrite or radicals derived from it (such as, e.g. the bicarbonate radical or nitrogen dioxide) indeed oxidize NADH, leading to the formation of NAD(+) and, via O-(2), of H(2)O(2). When peroxynitrite is generated in situ in the presence of HCO(3)(-)/CO(2), i.e. under conditions mimicking the in vivo situation, NAD(P)H effectively competes with other known scavengers of peroxynitrite.
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PMID:Reaction of peroxynitrite with reduced nicotinamide nucleotides, the formation of hydrogen peroxide. 1045 33

Nitrobenzene (NB) human cancer studies have not been reported, but animals studies have. Three rodent strains inhaling NB produce cancer at eight sites. B6C3F1 mice respond with mammary gland malignant tumors and male lung and thyroid benign tumors, F344/N male rats respond with liver malignant tumors and thyroid and kidney benign tumors, while females respond with endometrial polyps. Male Sprague-Dawley rats (CD strain) respond with liver benign tumors. NB is oxidized to various phenolic metabolites, while also being reduced in the cecum and systemically in the microsomes to nitrosobenzene (NOB), phenylhydroxylamine (PH), related free radicals, and aniline (AN). Based on structural and mechanistic similarities, NB compares with other animal and human carcinogenic nitroarenes and aromatic amines. Reduced NB first forms the nitroanion free radical, which can react with O2 to form superoxide O2*. Repeated NB dosing produces a persistent redox couple NOB<==>PH in red blood cells (RBCs) that generates met-Hb and expends NAD(P)H. NOB forms activated glutathione (GSH) conjugates. These biochemical effects may lead to critical redox imbalances and macromolecular binding. Known NB effects are hemosiderosis, methemoglobinemia, and anemia--and now dispersed cancer in rodents. On the basis of animal, metabolic and structure-activity studies, NB is determined to be a probable human carcinogen by any route of exposure.
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PMID:Nitrobenzene carcinogenicity in animals and human hazard evaluation. 1048 55

The oxidation of the fluorescent dye 2',7'-dichlorofluorescein (DCF) by horseradish peroxidase was investigated by optical absorption, electron spin resonance (ESR), and oxygen consumption measurements. Spectrophotometric measurements showed that DCF could be oxidized either by horseradish peroxidase-compound I or -compound II with the obligate generation of the DCF phenoxyl radical (DCF(.)). This one-electron oxidation was confirmed by ESR spin-trapping experiments. DCF(.) oxidizes GSH, generating the glutathione thiyl radical (GS(.)), which was detected by the ESR spin-trapping technique. In this case, oxygen was consumed by a sequence of reactions initiated by the GS(.) radical. Similarly, DCF(.) oxidized NADH, generating the NAD(.) radical that reduced oxygen to superoxide (O-(2)), which was also detected by the ESR spin-trapping technique. Superoxide dismutated to generate H(2)O(2), which reacted with horseradish peroxidase, setting up an enzymatic chain reaction leading to H(2)O(2) production and oxygen consumption. In contrast, when ascorbic acid reduced the DCF phenoxyl radical back to its parent molecule, it formed the unreactive ascorbate anion radical. Clearly, DCF catalytically stimulates the formation of reactive oxygen species in a manner that is dependent on and affected by various biochemical reducing agents. This study, together with our earlier studies, demonstrates that DCFH cannot be used conclusively to measure superoxide or hydrogen peroxide formation in cells undergoing oxidative stress.
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PMID:Phenoxyl free radical formation during the oxidation of the fluorescent dye 2',7'-dichlorofluorescein by horseradish peroxidase. Possible consequences for oxidative stress measurements. 1049 68

Cyclic dipeptides (c-Gly(2), c-Ser(2), c-Gly-Phe, etc.) were used as simple protein models to investigate the HOCl-induced generation and reactivity of chlorinated amide groups. The pH dependence of the kinetics of amide chlorination reveals that ClO(-) (not HOCl) is the reactive agent. N-Chlorinated cyclopeptides are stable up to 30 min, they exhibit narrow absorption bands around 215 nm, and they are capable of oxidizing certain biological substrates, the reactivity decreasing in the order GSH > ascorbate > methionine > NADH >> GSSG. The chloroamide is less reactive, but much more selective in its reactions, than HOCl or ClO(-); thus, with formation of the chloroamide prolonged oxidative effects, directed toward specific target molecules, can be expected. Chlorination of NADH, yielding a catalytically inactive species (NAD/Cl), was investigated in most detail because it is likely to be an important and highly lethal process. The chloroamide group is far more reactive toward NADH than chloroamines derived from primary amines. Chloronucleotides formed by reaction of ClO(-) with inosine, GMP, TMP, or UMP are capable of quantitative chlorine transfer to cyclopeptides; however, no chlorine transfer between the amide nitrogen and primary amines is detectable, in either direction. The results presented enable prediction of chlorine transfer cascades induced by HOCl/ClO(-), involving nucleotides, peptide amide groups, and final target molecules. Chlorinated NAD(P)H, as a stable terminal product of consecutive chlorine transfer reactions, might be a useful biological marker for assessing the role of HOCl in inflammatory events. Bromination by BrO(-) of cyclopeptides is more than two orders of magnitude faster than chlorination by ClO(-), and the reactivity of bromoamide with NADH exceeds that of chloroamide by more than four orders of magnitude.
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PMID:Consecutive halogen transfer between various functional groups induced by reaction of hypohalous acids: NADH oxidation by halogenated amide groups. 1052 95

Respiratory oscillation occurred during aerobic continuous culture of Saccharomyces cerevisiae. During oscillation, phase-related changes in NAD(P)H and GSH levels occur. Perturbation of oscillation and inhibition of respiration occurred when GSH or GSSG was injected; however, there was a phase delay in perturbation in the case of an injection during high respiration. The perturbation phase delay was not apparent when a combination of DL-buthionine-(S,R)-sulphoximine, GSH and 5-nitro-2-furaldehyde was injected. Perturbation by GSH injection caused the intracellular GSH concentration to increase, the GSSG concentration to decrease and the cessation of ethanol uptake. NAD(P)H during perturbation was inversely related to dissolved oxygen. Perturbation by calcium pantothenate and pyridoxal-HCl caused a period of enhanced respiration before oscillation returned. These results suggest that the NAD+/NADH redox is not directly involved in oscillation control and regulation involves glutathione metabolism. Possible regulation points include alcohol dehydrogenase inhibition and/or respiratory-chain inhibition.
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PMID:Involvement of glutathione in the regulation of respiratory oscillation during a continuous culture of Saccharomyces cerevisiae. 1053 95

Rats were exposed to a total dose of 0.75 Gy of gamma radiation from a 60Co source, receiving three doses of 0.25 Gy at weekly intervals. During two days before each irradiation, the animals received daily intragastric doses of 26 mg pantothenol or 15 mg beta-carotene per kg body mass. The animals were killed after the third irradiation session, and their blood and livers were analyzed. As found previously (Slyshenkov, V.S., Omelyanchik, S.N., Moiseenok, A.G., Trebukhina, R.V. & Wojtczak, L. (1998) Free Radical Biol. Med. 24, 894-899), in livers of animals not supplied with either pantothenol or beta-carotene and killed one hour after the irradiation, a large accumulation of lipid peroxidation products, as conjugated dienes, ketotrienes and thiobarbituric acid-reactive substances, could be observed. The contents of CoA, pantothenic acid, total phospholipids, total glutathione and GSH/GSSG ratio were considerably decreased, whereas the NAD/NADH ratio was increased. All these effects were alleviated in animals supplied with beta-carotene and were completely abolished in animals supplied with pantothenol. In the present paper, we extended our observations of irradiation effects over a period of up to 7 days after the last irradiation session. We found that most of these changes, with the exception of GSH/GSSG ratio, disappeared spontaneously, whereas supplementation with beta-carotene shortened the time required for the normalization of biochemical parameters. In addition, we found that the activities of glutathione reductase, glutathione peroxidase, catalase and NADP-dependent malate (decarboxylating) dehydrogenase ('malic enzyme') in liver were also significantly decreased one hour after irradiation but returned to the normal level within 7 days. Little or no decrease in these activities, already 1 h after the irradiation, could be seen in animals supplemented with either beta-carotene or pantothenol. It is concluded that pantothenol is an excellent radioprotective agent against low-dose gamma radiation.
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PMID:Protection by pantothenol and beta-carotene against liver damage produced by low-dose gamma radiation. 1054 25

Bilirubin is a well-known neurotoxin and presents a particular problem in newborn infants. This is partly due to the high incidence of unconjugated hyperbilirubinemia in that age group, but may also be due to increased vulnerability to bilirubin toxicity. The brain may be able to protect itself against bilirubin toxicity through a process of oxidation. The responsible enzyme is localized on the inner mitochondrial membrane and appears to be more active in glia than in neurons and to increase in activity with postnatal maturation. Here we have investigated the possibility that the responsible enzyme might be a cytochrome oxidase, malate dehydrogenase, or monoamine oxidase, all enzymes located on the inner mitochondrial membrane. Mitochondria were obtained from rat brains through homogenization and differential centrifugation in sucrose medium. The ability of mitochondrial membranes to oxidize bilirubin was measured by following the change in optical density at 440 nm of a bilirubin solution to which a membrane suspension had been added. The activity was not changed by in vitro inhibitors of malate dehydrogenase or monoamine oxidase, but was moderately inhibited by ketoconazole and clotrimazole, both known inhibitors of hepatic cytochrome P450 oxidases. Activity was inhibited by depletion of cytochrome c in the mitochondria and reconstituted by reintroducing cytochrome c into the reaction mixture. The reaction was not modified by the addition of a free radical quencher, but was inhibited by removal of oxygen from the reaction mixture. The activity was significantly inhibited by cyanide. Activity was retained in a 100,000-g pellet and was not influenced by the addition of NAD, NADP, NADH, NADPH, GSH, or GSSH to this pellet. We conclude that the bilirubin-oxidizing activity in brain mitochondrial membranes is cytochrome c dependent, but does not appear to be unequivocally identifiable as a cytochrome P450 oxidase.
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PMID:Oxidation of bilirubin in the brain-further characterization of a potentially protective mechanism. 1056 68

Both sorbitol accumulation-linked osmotic stress and "pseudohypoxia" [increase in NADH/NAD+, similar to that in hypoxic tissues, and attributed to increased sorbitol dehydrogenase (1-iditol:NAD+ 5-oxidoreductase; EC 1.1.1.14; SDH) activity] have been invoked among the mechanisms underlying oxidative injury in target tissues for diabetic complications. We used the specific SDH inhibitor SDI-157 [2-methyl-4(4-N,N-dimethylaminosulfonyl-1-piperazino)pyrimid ine] to evaluate the role of osmotic stress versus "pseudohypoxia" in oxidative stress occurring in diabetic precataractous lens. Control and diabetic rats were treated with or without SDI-157 (100 mg/kg/day for 3 weeks). Lens malondialdehyde (MDA) plus 4-hydroxyalkenals (4-HA), MDA, GSH, and ascorbate levels, as well as the GSSG/GSH ratios, were similar in SDI-treated and untreated control rats, thus indicating that SDI-157 was not a prooxidant. Intralenticular osmotic stress, manifested by sorbitol levels, was more severe in SDI-treated diabetic rats (38.2+/-6.8 vs 21.2+/-3.5 micromol/g in untreated diabetic and 0.758+/-0.222 micromol/g in control rats, P<0.01 for both), while the decrease in the free cytosolic NAD+/NADH ratio was partially prevented (120+/-16 vs 88+/-11 in untreated diabetic rats and 143+/-13 in controls, P<0.01 for both). GSH and ascorbate levels were decreased, while MDA plus 4-HA and MDA levels were increased in diabetic rats versus controls; both antioxidant depletion and lipid aldehyde accumulation were exacerbated by SDI treatment. Superoxide dismutase (superoxide:superoxide oxidoreductase; EC 1.15.1.1), GSSG reductase (NAD[P]H:oxidized-glutathione oxidoreductase; EC 1.6.4.2), GSH transferase (glutathione S-transferase; EC 2.5.1.18), GSH peroxidase (glutathione:hydrogen-peroxide oxidoreductase; EC 1.11.1.9), and cytoplasmic NADH oxidase activities were increased in diabetic rats versus controls, and all the enzymes but GSH peroxidase were up-regulated further by SDI. In conclusion, sorbitol accumulation and osmotic stress generated oxidative stress in diabetic lens, whereas the contribution of "pseudohypoxia" was minor. SDIs provide a valuable tool for exploring mechanisms of oxidative injury in sites of diabetic complications.
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PMID:Interaction between osmotic and oxidative stress in diabetic precataractous lens: studies with a sorbitol dehydrogenase inhibitor. 1059 Nov 49

Because of the importance of glutathione (GSH) and glutathione disulfide (GSSG) in cellular signal transduction, gene regulation, redox regulation, and biochemical homeostasis, accurate determination of cellular glutathione levels is critical. Several procedures have been developed, but many suffer from overestimating GSSG or from cellular substances interfering or competing with GSH determination. Assays based on HPLC, with enzymatic reduction of GSSG by glutathione reductase and NADPH, appear to be valid but are limited in sample throughput and availability of equipment. The fluorescence probe o-phthalaldehyde (OPA, phthalic dicarboxaldehyde) reacts with GSH and has a high quantum yield, yet its use has been limited due to unidentified interfering and fluorescence-quenching substances in liver. This paper describes assay conditions under which these limitations are avoided. By using a phosphate-buffered assay at lower pH, interference with nonspecific reactants is minimal. Since enzymatic reduction is not possible due to the reaction of OPA with NAD(P)H and other stronger reducing agents, leading to an overestimation of GSSG levels, dithionite was used to reduce GSSG. High sample throughput combined with sensitive (20-pmol limit of detection) and accurate determination of GSH and GSSG using OPA is achievable with any monochromatographic spectrofluorometer. Sample preparation and storage conditions are described that return the same levels of GSH and GSSG for at least 4 weeks.
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PMID:Determining glutathione and glutathione disulfide using the fluorescence probe o-phthalaldehyde. 1080 24

Isothiocyanates (ITCs) are abundant in the human diet. Many potently inhibit tumorigenesis induced by a wide variety of chemical carcinogens in rodents. Recently, we observed that several ITCs accumulated to very high concentrations in cultured cells and that their accumulated levels were closely related to their potencies in inducing phase II enzymes [NAD(P)H:quinone reductase and glutathione transferases] that detoxify carcinogens. To elucidate the molecular mechanism responsible for this accumulation, the intracellular chemical identities of two ITCs, sulforaphane [SF, 1-isothiocyanato-(4R,S)-(methylsulfinyl)butane] and benzyl-ITC, were investigated in murine hepatoma cells. Both ITCs accumulated very rapidly to high intracellular concentrations, but, remarkably, most of the intracellular forms of the ITCs were dithiocarbamates resulting from conjugation with reduced glutathione (GSH). For example, the intracellular concentration reached 6.4 mM when cells were exposed to 100 microM SF for 30 min at 37 degrees C and 95% of the accumulated product was the GSH conjugate. Cellular accumulation of each ITC was accompanied by a profound reduction in cellular GSH levels. These findings, together with our previous observation that accumulation of ITCs depended on cellular GSH levels, strongly suggest that intracellular conjugation of ITCs with GSH is mainly responsible for ITC accumulation. Surprisingly, rapid accumulation to high concentrations also occurred when cells were exposed to the GSH-ITC conjugates. However, these conjugates were apparently not absorbed intact, but were hydrolyzed extracellularly to free ITCs that were taken up by the cells. This conclusion is supported by the finding that suppression of dissociation of the conjugates by excess GSH or other thiols blocks accumulation of the conjugates.
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PMID:Role of glutathione in the accumulation of anticarcinogenic isothiocyanates and their glutathione conjugates by murine hepatoma cells. 1083 7

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