Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0242706 (hyperoxia)
5,219 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rhodotorula mucilaginosa is an obligate aerobic yeast which contains a high concentration of carotenoid pigment. To test whether carotenoids are able to protect R. mucilaginosa against oxidative injury, yeast cells in liquid culture were incubated with duroquinone (DQ) (100 microM), a redox-cycling quinone known to generate intracellular O2-. or were grown in a hyperoxic atmosphere (80% O2) under conditions where carotenoid concentrations were altered either intracellularly or extracellularly. Neither of these oxidative challenges affected cell growth unless carotenogenesis was blocked by the addition of diphenylamine (50 microM). In the diphenylamine-treated nonpigmented cells, growth was completely inhibited by DQ and by hyperoxia. In normoxia, however, diphenylamine alone reduced growth by only 30%. The growth inhibition observed in diphenylamine-treated cells exposed to hyperoxia was primarily mycocidal rather than mycostatic since plating of these cells onto solid media revealed that only 25% of the cells were viable after 50 h of incubation when compared to plated control cells. Addition of 10 microM beta-carotene to diphenylamine-treated cells completely prevented the growth inhibition caused by either hyperoxia or DQ. Carotenoids, therefore, are able to prevent oxidant-induced cytotoxicity in R. mucilaginosa. Analysis of the absorption spectra of chloroform extracts of beta-carotene-supplemented cells showed that beta-carotene, not the endogenous carotenoid, torularhodin, was the major carotenoid present in these cells. Superoxide dismutase (SOD) activity in R. mucilaginosa was compared with that of another yeast, Saccharomyces cerevisiae by two methods: (i) activity staining of proteins separated by gel electrophoresis and (ii) measurement of inhibition of ferricytochrome c reduction. By these techniques, the R. mucilaginosa SOD activity had the characteristics of Mn-SOD. No Cu/ZnSOD activity was detected. Thus, the apparent absence of Cu/ZnSOD may make the antioxidant capability of endogenous carotenoids even more critical in preventing oxidative damage in R. mucilaginosa.
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PMID:The role of carotenoids in preventing oxidative damage in the pigmented yeast, Rhodotorula mucilaginosa. 265 Jun 23

Experiments were designed to determine the effects of oxygen-derived free radicals on the production and biological activity of endothelium-derived relaxing factor or factors released by acetylcholine. Rings of canine coronary arteries without endothelium (bioassay rings) were superfused with solution passing through a canine femoral artery with endothelium. Superoxide dismutase caused maximal relaxation of the bioassay ring when infused upstream, but not downstream, of the femoral artery; this effect of superoxide dismutase was inhibited by catalase. Infusion of acetylcholine relaxed the bioassay rings because it released a labile relaxing factor (or factors) from the endothelium. When infused below the femoral artery, superoxide dismutase and, to a lesser extent, catalase augmented the relaxations to acetylcholine. Superoxide dismutase, but not catalase, doubled the half-life of the endothelium-derived relaxing factor(s). This protective effect of the enzyme was augmented fivefold by lowering the oxygen content of the perfusate from 95 to 10%. These data demonstrate that: superoxide anions inactivate the relaxing factor(s) released by acetylcholine from endothelial cells and hyperoxia favors the inactivation of endothelium-derived relaxing factor(s).
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PMID:Superoxide anions and hyperoxia inactivate endothelium-derived relaxing factor. 301 Jul 44

Buthionine sulfoximine (BSO), an inhibitor of de novo synthesis of glutathione (GSH), was used to deplete rats of GSH and determine the effect of treatment on antioxidant enzyme responses, lung injury, and the susceptibility to concurrent sublethal or lethal hyperoxia. In a preliminary experiment, total lung nonprotein sulfhydryl (NPSH) and GSH levels were measured at various times after single doses of BSO. The lowest concentrations were observed at 12 to 18 h. These experiments were used to establish a repeated dosing protocol for more prolonged GSH depletion. The lungs of rats treated with BSO for 4 days demonstrated markedly decreased GSH and NPSH levels (10 to 40% of control values) and glutathione peroxidase activity (45 to 60% of control values). Superoxide dismutase activities were elevated, glutathione reductase activity was slightly elevated, and catalase activity was unchanged. These changes were dose-responsive. The lungs of treated rats were grossly and microscopically normal. BSO treatment of additional rats did not increase susceptibility to lethal hyperoxia (greater than 98% oxygen). Combined treatment of rats with both BSO and sublethal hyperoxia (80% oxygen) for 4 days did not alter the biochemical responses demonstrated by rats treated solely with BSO. The marked increase in catalase activity obtained after hyperoxia alone was not observed in rats treated with both hyperoxia and BSO. The lungs of saline- and BSO-treated rats exposed to sublethal hyperoxia demonstrated a patchy distribution of slight perivascular and peribronchiolar edema.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The pulmonary effects of buthionine sulfoximine treatment and glutathione depletion in rats. 320 1

Superoxide dismutase is considered important in protection of aerobes against oxidant damage, and increased tolerance to oxidant stress is associated with induction of this enzyme. However, the importance of superoxide dismutase in this tolerance is not clear because conditions which promote the synthesis of superoxide dismutase likewise affect other antioxidant enzymes and substances. To clarify the role of superoxide dismutase per se in organismal defense against oxidant-generating drugs, we employed Escherichia coli transformed with multiple copies of the gene for bacterial iron superoxide dismutase. These bacteria have greater than ten times the superoxide dismutase activity of wild-type E. coli but, importantly, are normal in other oxidant defense parameters including catalase, peroxidases, glutathione, and glutathione reductase. High superoxide dismutase and control bacteria were exposed to the O2- -generating drug paraquat and to elevated pO2. We find; high superoxide dismutase E. coli are more readily killed by paraquat under aerobic, but not anaerobic, conditions. During exposure to paraquat, high superoxide dismutase E. coli accumulate more H2O2. Coincidentally, the reduced glutathione content of high superoxide dismutase E. coli declines more than in control E. coli. E. coli with high superoxide dismutase activity are also more readily killed by hyperoxia. Interestingly, the susceptibility of the parental and high superoxide dismutase E. coli to killing by exogenous H2O2 is not significantly different. Thus, under these experimental conditions, greatly enhanced superoxide dismutase activity accelerates H2O2 formation. The increased H2O2 probably accounts for the exaggerated sensitivity of high superoxide dismutase bacteria to oxidant-generating drugs. These results support the concept that the product of superoxide dismutase, H2O2, is at least as hazardous as the substrate, O2-. We conclude that effective organismal defense against reactive oxygen species may require balanced increments in antioxidant enzymes and cannot necessarily be improved by increases in the activity of single enzymes.
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PMID:Superoxide dismutase-rich bacteria. Paradoxical increase in oxidant toxicity. 354 14

An animal model was established to study the toxic effects of hyperoxia and the consequent changes in intracellular antioxidant status. Superoxide dismutase, catalase and glutathione peroxidase activities were measured in erythrocytes, liver and lung, in addition to cellular glutathione concentrations and its associated metabolism. Overt cellular damage was assessed biochemically by measurement of lipid peroxidation, hydrogen peroxide-induced haemolysis and osmotic fragility. Pathological changes were assessed by light and electron microscopy. Up to 11 days exposure of rats to 80% oxygen was not lethal, but resulted in overt cellular damage to red blood cells (haemoglobin concentration decreased from 13.8 +/- 1.4 (SD) g dl-1 to 12.4 +/- 0.5 g dl-1; hydrogen peroxide-induced haemolysis increased from 7.7 +/- 1.6% to 75.1 +/- 13.5% after 11 days of hyperoxia) and to cells of lung (4-fold increase in lipid peroxidation) as well as a biochemical adaptation to the increased concentration of oxygen metabolites (superoxide dismutase increased 3-fold, catalase 5-fold and glutathione peroxidase 2-fold). It is suggested that red cell hydrogen peroxide-induced haemolysis and reduced glutathione concentration may be useful indicators of oxidant stress in the clinical situation.
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PMID:Tissue responses to hyperoxia. Biochemistry and pathology. 360 20

It has recently been determined that fetal lung antioxidant enzyme activity markedly increases late in gestation. A test was made of whether this normal late-in-gestation change in O2-protective enzymes would be responsive to the maturing effect of hormonal (glucocorticoid) treatment. Pregnant rats received 0.2 mg/kg of dexamethasone (or saline) at 48 and 24 hours prior to delivery of their fetuses on gestational days 19, 20, 21, and 22 (newborn). Lung disaturated phosphatidylcholine showed an expected response to prenatal dexamethasone exposure with significant elevations of surfactant lipid at gestational days 20 and 21. A similar effect of prenatal dexamethasone treatment on the lung antioxidant defensive system was found. Superoxide dismutase, catalase, and glutathione peroxidase--enzymes protective against hyperoxia-induced lung injury--showed an accelerated pattern of maturation with significant increases in the dexamethasone-treated fetal lungs compared with control fetal lung enzyme levels at gestational days 20 and 21. The results suggest that prenatal dexamethasone treatment may have dual benefits when used in impending premature deliveries--that is, it may stimulate maturation of both the surfactant system and also the antioxidant enzyme system, and this maturation can help protect the premature newborn's lungs from the toxic complications of hyperoxic therapy that may be required because of immaturity.
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PMID:Dexamethasone stimulation of fetal rat lung antioxidant enzyme activity in parallel with surfactant stimulation. 384 97

The oxidant damage of lung tissue during in vivo hyperoxic exposure appears to be amplified by neutrophils that release toxic amounts of oxygen metabolites. In our studies cloned lung epithelial cells (L2 cells), lung fibroblasts, and pulmonary artery endothelial cells were cultured under either ambient (Po(2) approximately 140 torr) or hyperoxic (Po(2) approximately 630 torr) conditions for 48 h (24 h for endothelial cells). After cultivation, phorbol myristate acetate- or opsonized zymosan-stimulated neutrophils were added to the cultivated monolayers for 4 h, and lung cell damage was quantitated using (51)Cr release as an index. The data show that stimulated neutrophils are able to injure the three lung cell lines tested, with endothelial cells being highly susceptible to this injury and L2 cells being slightly more susceptible than lung fibroblasts. The studies also demonstrate that all three lung cell lines exposed to sustained hyperoxia are more susceptible to neutrophil-mediated cytotoxicity than their time-matched air controls. Hydrogen peroxide was the main toxic oxygen metabolite because catalase (2,500 U/ml) completely protected the target cells. Equivalent quantities of hydrogen peroxide generated by glucose oxidase instead of by neutrophils gave a similar degree of target cell injury. Superoxide dismutase at high concentrations (250 mug/ml) provided some protection. Other systems that detoxify oxygen metabolites were without protective effect. These findings indicate that the increase in susceptibility of lung cells to neutrophil-mediated oxidant damage is a toxic effect of hyperoxia on lung cells. This specific manifestation of oxygen damage provides insight into the integration between primary mechanisms (oxygen exposure) and secondary mechanisms (release of oxygen metabolites by neutrophils) with respect to the cellular basis for pulmonary oxygen toxicity.
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PMID:Lung cell oxidant injury. Enhancement of polymorphonuclear leukocyte-mediated cytotoxicity in lung cells exposed to sustained in vitro hyperoxia. 628

Increased intracellular production of oxygen radicals is a major etiology of cell damage from many quinoid antibiotics, environmental toxicants, and hyperoxia. Enhancing the intracellular content of protective enzymes can provide a means of limiting biological damage caused by free radicals. Liposomal entrapment and intracellular delivery of superoxide dismutase to cultured porcine aortic endothelial cells increased the specific activity of cellular superoxide dismutase 6 to 12-fold. This augmented superoxide dismutase activity persisted in cultured endothelial cell monolayers and rendered these cells resistant to oxygen-induced injury. Culture of confluent endothelial cells in hyperoxia increased 51Cr and lactate dehydrogenase release in an oxygen concentration-dependent manner. Superoxide dismutase-augmented endothelial cells were resistant to oxygen damage compared to untreated controls, in a superoxide dismutase concentration-dependent manner. Free superoxide dismutase in the absence or presence of liposomes containing no enzyme had no effect on cellular enzyme activity and did not protect from oxygen damage. Liposomes made from saturated fatty acid-containing phospholipids had a small but significant protective effect on oxygen-induced cell damage. These liposomes probably increased endothelial cell membrane saturated lipid content and thereby decreased peroxidative damage when the cells were exposed to hyperoxia. Conversely, preincubation of cells with arachidonic acid increased cell arachidonic acid content, sensitivity to hyperoxia, and hyperoxia-induced production of thiobarbituric acid material. These data suggest that intracellular delivery of superoxide dismutase prevents oxygen-induced cell damage and that superoxide is an important mediator of cellular oxygen toxicity.
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PMID:Liposome-mediated augmentation of superoxide dismutase in endothelial cells prevents oxygen injury. 668 7

Superoxide dismutase activity of alveolar macrophages, lung, liver, retina and choroid has been studied in rats and rabbits exposed to oxygen at high concentration by itself and in combination with D-penicillamine. Prolonged hyperoxia caused an increase in superoxide dismutase activity while D-penicillamine was found to inhibit the inductive effect of oxygen. It is assumed that the antioxidative effect of D-penicillamine makes it unnecessary to augment the production of superoxide dismutase.
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PMID:Experimental data on the prevention of retrolental fibroplasia by D-penicillamine. 689 55

The role of animal age in the lethal response to > 98% oxygen has been extensively studied, with the observation that neonatal rats were resistant while mature animals were sensitive. Antioxidant enzymes increased during the oxygen exposure in neonatal but not in mature rats, suggesting they were important in the age-related toxicity difference. Because no studies had compared the response of mature and old rats to hyperoxia, we exposed Fischer 344 rats, aged 2 and 27 mo, to > 98% oxygen. Unexpectedly, the old rats lived significantly longer than young, 114 and 65 h, respectively. No histopathological differences were found to explain the results. Of the antioxidants, only glutathione peroxidase (GPx) activity was higher in the lungs of nonexposed old rats. Superoxide dismutase (SOD) was higher in the young, results opposite those expected if SOD was important in the lethality difference. No antioxidant induction occurred in the old oxygen-exposed rats. These results suggest that although there may be a role for GPx, mechanisms in addition to antioxidant protection and inflammation are likely responsible for the age-related difference in hyperoxia lethality.
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PMID:An age-related difference in hyperoxia lethality: role of lung antioxidant defense mechanisms. 773 96


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