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)

Nitrosobenzene (NOB) formed acid labile conjugates with reduced glutathione (GSH) and hemoglobin within red cells. In vitro, NOB rapidly reacted with GSH with formation of phenylhydroxylamine (PH), oxidized glutathione (GSSG), and a water-soluble compound identified as glutathionesulfinanilide (GSO-AN). Free aniline (AN), aminophenols and azoxybenzene were not detected. The proportion of PH formed increased with increasing GSH concentration and at higher pH values. Spectroscopic analysis revealed the formation of a labile adduct following a second order reaction (K = 5 x 10(3) M-1 . sec-1 at pH 7.4 and 37 degrees). This reaction was reversible because nearly all NOB could be extracted with ether from the labile intermediate. On the other hand, the labile intermediate was transformed into GSO-AN (with increasing rate at lower pH values) or it was cleaved by GSH with formation of GSSG and PH. Intermediate formation of NOB and thiol radicals was ruled out by analysis of the equilibrium data. A tentative scheme is presented for the proposed reaction mechanism.
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PMID:Reactions of nitrosobenzene with reduced glutathione. 3 85

The formation of glutathione (GSH) conjugate in the detoxification of [1-14C]-naphthalene and [naphthyl-14C]-carbaryl was investigated using rat liver homogenate. The mercapturic acid conjugate in rats was also investigated by collection of urine after intraperitoneal injection of 14C substrates. The formation of water-soluble metabolites in vitro from naphthalene was dependent on the amount of glutathione added, but this was not seen in carbaryl metabolism. In vitro, the metabolism of [1-14C]-naphthalene produced 50% GSH conjugates in the incubation mixture, whereas in vivo the metabolism of this compound produced 65% mercapturic acid conjugate in the urine. There was no evidence of GSH or mercapturic acid conjugate in the metabolism of [naphthyl-14C]-carbaryl in vitro and in vivo. This conclusion was made by comparing the nature and chemical characteristics of GSH and mercapturic acid conjugates formed in [1-14C]-naphthalene metabolism. With the aid of the specific enzyme (e.g. beta-glucuronidase and sulfatase) and acid hydrolysis, the water-soluble metabolites of [naphthyl-14C]-carbaryl were tentatively recognized as glucuronide or sulfate conjugated mainly with 5,6-dihydro-5,6-dihydroxycarbaryl or N-hydroxy-methyl carbaryl and their hydrolytic products. This data demonstrated that the substituent group on the naphthalene molecule may affect the significance of GSH conjugation.
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PMID:Glutathione and mercapturic acid conjugations in the metabolism of naphthalene and 1-naphthyl N-methylcarbamate (carbaryl). 12 Feb 42

Ungerminated Neurospora crassa conidia were incubated at 0, 50, and 100% relative humidity, giving rise to conidia in dry, quasi-dry, and wet hydration states, respectively. Metabolic activity was detected by monitoring levels of reduced glutathione (GSH), oxidized glutathione (GSSG), and the soluble-amino acid pools as a function of incubation time. Wet conidia (approximately 65% water content) exhibited significant metabolic activity as evidenced by: (i) reduction of GSSG to GSH, (ii) degradation of GSH, and (iii) changes in the pool sizes of certain amino acids. GSSG accumulated slowly in dry conidia (less than 5% water content) and more rapidly in quasi-dry conidia (approximately 13% water content), indicating that enzymatic reduction of GSSG is inactive in these states. Longevity and thermal resistance were high for dry conidia and low for wet conidia, but were not influenced by variation in GSSG content. The water content of conidia exhibited a hysteresis effect in that at a given relative humidity previously dried conidia attained a lower water content than freshly harvested conidia.
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PMID:Correlation of enzymatic activity and thermal resistance with hydration state in ungerminated Neurospora conidia. 15 Oct 96

Liposomes were prepared from phospholipids extracted from biological membranes. A comparison was made between the peroxidation rate in handshake liposomes and in sonicated liposomes. The smaller sonicated liposomes were more vulnerable to peroxidation, probably because of the smaller radius of curvature, which results in a less dense packing of lipid molecules in the bilayer and a facilitated action of water radicals produced by the X-irradiation. High oxygen enhancement ratios were obtained, especially at low dose rates, suggesting the operation of slowly progressing chain reactions initiated by ionizing radiation. Three compounds were tested for their ability to protect the liposomal membranes against lipid peroxidation. The naturally occurring compounds reduced glutathione (GSH) and vitamin E(alpha-T) and the powerful radiation protector cysteamine (MEA). All three molecules could protect the liposomes against peroxidation. The membrane-soluble compound vitamin E was by far the most powerful. About 50 per cent protection was achieved by using 5 X 10(-6) M alpha-T, 10(-4) M GSH and 5 X 10(-4) M MEA. The fatty acid composition of the lipids altered drastically as a result of the irradiation. Arachidonic acid and docosahexanoic acid were the most vulnerable of the fatty acids. Very efficient protection of these polyunsaturated fatty acids could be obtained with relatively low concentrations of vitamin E built into the membranes.
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PMID:Protection of liposomal lipids against radiation induced oxidative damage. 31 91

Chlorine dioxide (Cl02) has been proposed as an alternative disinfectant to chlorine to avoid formation of organohalides. Cl02 and metabolites, chlorite (Cl0-2) and chlorate (Cl0-3) in drinking water produced decreases in rat and chicken blood GSH. The GSH dependent system was studied in rat and chicken blood after chronic treatment for 6 months with CL02 (0, 1, 10, 100, 1000 MG/L), Cl0-2 or Cl0-3 (10, 100 mg/l) in drinking water. There was a 60% increase in GSH reductase in the Cl02 treatment groups of rats and chickens. A similar increase was shown in rats treated with Cl0-2 but with Cl0-3 no change was observed. GSH peroxidase was without change in rat but chickens drinking 1000 mg/l Cl02 had decreased activity. Catalase was significantly higher than control in rat and chicken in the 1000 mg/l groups. However, catalase activity was decreased in rat treated with Cl0-2 and at the same time that GSH was decreased. These studies support the view that catalase is the first line of defense against the oxidative stress of Cl02 in rat and chicken erythrocytes.
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PMID:Effect of chlorine dioxide and metabolites on glutathione dependent system in rat, mouse and chicken blood. 54 25

Cell division in fertilized sea urchin eggs was reversibly inhibited when the ketoaldehyde phenyl glyoxal (PG) at a concentration of 0.1 mM was added to eggs for ten minutes prior to the formation of the mitotic spindle. We investigated whether inhibition of mitosis was due to PG binding to the cell surface (as previously suggested by Stein and Berestecky, '74) or to some intracellular effect. When 14C-PG was added to eggs, label was readily taken up into the egg cytoplasm; very little label was associated with the egg surface. In the cytoplasm PG combined with equimolar amounts of reduced glutathione (GSH), decreasing the levels of cellular GSH to less than 15% of normal and accounting for at least 50% of the PG taken up by eggs. The concentrations of oxidized and protein-bound glutathione were unaffected by PG treatment. We showed that glyoxalase enzymes were present in sea urchin eggs and were capable of metabolizing the PG-GSH complex, thereby restoring GSH to normal levels after PG was removed from the sea water. Though some other effect of PG cannot be ruled out, the major fate of PG in eggs was to combine with GSH, and the transient decrease in GSH which resulted could lead to inhibition of mitosis. While other reports (Nath and Rebhun, '76; Oliver et al., '76) have shown that reagents which oxidize GSH disrupt microtubule-related events, our results showed that such inhibition could be caused by decreased GSH levels alone.
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PMID:Involvement of glutathione in the inhibition of sea urchin egg mitosis by phenyl glyoxal. 57 30

Studies were conducted in an attempt to define a biochemical index of selenium toxicity rather than weight loss, liver disease and death. Rats, maintained on selenium deficient diets, received in drinking water various levels of selenium as Na2SeO3(0.1, 1.0, 1.5, 2.0 ppm). Changes in selenium dependent glutathione peroxidase (GSH-Px) activities and specific activities (nCi75Se/ug Se) were determined in liver, kidney and plasma at baseline and two and ten weeks after repletion. In intial selenium deficient rats, GSH-Px activities were markedly depressed and specific activities elevated as compared to 0.1 ppm controls. After two weeks, liver and plasma GSH-Px activiities increased, and plasma, liver and kidney specific activities decreased in a concentration dependent manner. In kidney, there were no differences in enzyme activity at either two or ten weeks. At ten weeks, liver GSH-Px activities continued to increase in the 1.0 ppm group, but were depressed at both the 1.5 and 2.0 ppm levels. Specific activities were also depressed in liver and excretion was not increased at these levels. This suggests a biochemical toxicity in liver at levels above 1.0 ppm after ten weeks, prior to the onset of gross pathological changes.
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PMID:The effects of different levels of selenium administered to rats in drinking water on distribution and glutathione peroxidase. 68 71

Chloramines, compounds made up of chlorine and ammonia, when present in tap water used for dialysis cause methemoglobinemia and hemolysis. Ascorbic acid addition has been reported to effectively neutralize chloramines in vitro and in patients dialyzed with the single batch dialysis delivery system. We extended these observations to patients dialyzed with the proportioning dialysis delivery system where exposure time of ascorbic acid to chloramines is shorter. This may be important since we found that the half time of the reaction between ascorbic acid and chloramines is 4 minutes. Red cell oxidant sensitivity in 15 patients was assessed by incubating red cells with ascorbate-cyanide and measuring methemoglobin which averaged 2.17 +/- 0.42 g/100 ml (SEM) before dialysis and 2.87 +/- 0.52 g/100 ml after dialysis (NS). Reduced glutathione (GSH) levels were also measured as an index of red cell oxidant damage. GSH decreased from a mean of 7.40 +/- 0.59 micromoles/g Hb before dialysis to 6.98 +/- 0.52 micronmoles/g Hb after dialysis (P less than 0.01). In 2 patients there was no change in 51Cr red cell survival when dialyzed on either the proportioning system or other chloramine free systems. We conclude that addition of ascorbic acid to neutralize chloramines in tap water is also effective when using the proportioning dialysis delivery system.
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PMID:Prevention of chloramine-induced hemolysis in dialyzed patients. 69 6

Incubation of 15-keto[3H]prostaglandin F2alpha with glutathione (GSH) produced a metabolite of 15-keto-prostaglandin F2alpha which was not extractable from aqueous solution and thus termed 'water-soluble metabolite'. The addition of cytosol of guinea pig liver to the incubation mixture increased the formation of water soluble metabolite of 15-keto-prostaglandin F2alpha 3-fold. The conversion of 15-keto-prostaglandin F2alpha to water soluble metabolite in both the presence and absence of enzyme was linear during 10 min of incubation and required 2.5 mM GSH for maximal activity. Liver and kidney cytosol possess about 70 and 25 times, respectively, as much activity as compared to lung cytosol. Chromatographic analysis of the water soluble metabolite obtained from incubation of either 15-keto[3H]prostaglandin F2alpha and GSH or [3H]GSH and 15-keto-prostaglandin F2alpha showed that the water-soluble metabolite was an adduct of 15-keto-prostaglandin F2alpha and GSH. The addition of prostaglandin A1, a substrate of GSH S-transferases, to the incubation mixture competitively inhibited the formation of the water-soluble metabolite of 15-keto[3H]prostaglandin F2alpha. Presumably, 15-keto-prostaglandin F2alpha and other 15-keto-prostaglandins are converted to GSH conjugates by GSH S-transferases. This indicates that 15-keto-metabolites produced by prostaglandin dehydrogenase may be further metabolized to GSH conjugates.
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PMID:Conjugation of 15-keto-prostaglandins by glutathione S-transferases. 70 49

The purpose of this study was to investigate the hypothesis that paraquat pulmonary toxicity results from cyclic reduction-oxidation of paraquat with sequential generation of superoxide radicals and singlet oxygen and initiation of lipid peroxidation. In vitro mouse lung microsomes catalyzed an NADPH-dependent, single-electron reduction of paraquat. Incubation of paraquat with NADPH, NADPH-cytochrome c reductase, and purified microsomal lipid increased malondialdehyde production is a concentration dependent manner. Addition of either superoxide dismutase or a single oxygen trapping agent 1,3-dipheylisobenzo furan inhibited paraquat stimulated lipid peroxidation. In vivo, pretreatment of mice with phenobarbital decreased paraquat toxicity, possibly by competing for electrons which might otherwise reduce paraquat. In contrast, paraquat toxicity in mice was increased by exposure to 100% oxygen and by deficiencies of the antioxidants selenium, vitamin E, or reduced glutahione (GSH). Paraquat, given IP to mice, at 30 mg/kg, decreased concentrations of the water-soluble antioxidant GSH in liver and lipid soluble antioxidants in lung. Oxygen-tolerant rats, which hae increased activities of pulmonary enzymes which combat lipid peroxidation, were also tolerant to lethal doses of paraquat as indicated by an increased paraquat LT50. Furthermore, rats chronically exposed to 100 ppm paraquat in the water had elevated pulmonary activities of glucose-6-phosphate dehydrogenase and GSH reductase. These results were consistent with the hypothesis that lipid peroxidation is involved in the toxicity of paraquat.
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PMID:Paraquat toxicity: proposed mechanism of action involving lipid peroxidation. 101 17

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