UMLS:C0242706 - FACTA Search

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Query: UMLS:C0242706 (hyperoxia)
5,219 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

HA-1 hamster fibroblasts receiving fresh media every 24 h were continuously passaged in progressively increasing O2 concentrations for 18 mo (designated O2R95). These cells were significantly more resistant than parental HA-1 to clonogenic inactivation mediated by 95% O2 without media replacement. The O2R95 cell line exhibited increases in the activities of catalase (CAT), Mn superoxide dismutase (MnSOD), Cu,Zn superoxide dismutase (Cu,Zn SOD), and glutathione peroxidase (GPx). O2R95 cells demonstrated uniformly distributed increased staining for CAT, MnSOD, Cu,Zn SOD, and GPx proteins, as determined by immunohistochemistry. Cellular resistance to and metabolism of 4-hydroxy-2-nonenal (4HNE), a toxic byproduct of lipid peroxidation implicated in mechanisms of O2 toxicity, was examined in HA-1 and O2R95 cell lines. O2R95 cells were significantly more resistant to 4HNE cytotoxicity, which was accompanied by a significant increase in 4HNE metabolism. O2R95 cells also demonstrated an increase in total glutathione (GSH) and glutathione S-transferase (GST) activity, an enzymatic system believed to be involved with 4HNE metabolism. Furthermore, homogenates from O2R95 cells consumed greater quantities of 4HNE in the presence of NADPH (but not NADH, NAD+, or NADP+), suggesting that an enzyme(s) utilizing NADPH contributes to 4HNE metabolism, resistance to 95% O2 and 4HNE as well as increased total GSH, antioxidant enzyme activities, and NADPH-dependent metabolism of 4HNE, persisted in O2R95 cells for 75 days of growth in 21% O2. These findings are compatible with the hypothesis that aldehydic byproducts of lipid peroxidation contribute to mechanisms of O2 toxicity and the selective pressure exerted by exposure of cells to hyperoxia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:A stable O2-resistant cell line: role of lipid peroxidation byproducts in O2-mediated injury. 161 58

The lung is especially sensitive to a variety of vastly different agents and conditions including hyperoxia, certain drugs and xenobiotics, particulate debris, and ischemia/reperfusion. There is a growing body of experimental data to suggest that most, if not all, of these agents or conditions mediate pulmonary injury by forming reactive O2 metabolites such as O2-., H2O2.OH, HOCl, and RNHCl. The presence mechanisms by which these different agents converge to produce free radical-mediated pulmonary injury is not entirely clear. The lung does contain several metabolic pathways that will produce large amounts of reactive O2 metabolites. For example, hyperoxia-induced pulmonary injury may be mediated by oxidants produced by both mitochondrial and microsomal electron transport. Certain drugs and xenobiotics may be metabolized by nonspecific flavoproteins found in the mitochondrial electron transport chain and associated with microsomal mixed function oxidase system to yield a variety of free radicals and oxidants. Inhalation of particulate debris will activate resident phagocytic leukocytes to produce large quantities of cytotoxic oxidants. Ischemia and reperfusion appear to produce substantial amounts of xanthine oxidase-derived oxy-radicals that recruit and activate inflammatory phagocytes to produce cytotoxic HOCl and N-chlorinated oxidants. Finally, inappropriate metabolism of arachidonate by prostaglandin synthetase in the presence of NADH (NADPH) produces a burst of O2-. The fact that the lung contains so many different metabolic avenues for oxidant and free radical production suggests that this particular organ may be the most sensitive to oxidative insult.
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PMID:Metabolic sources of reactive oxygen metabolites during oxidant stress and ischemia with reperfusion. 265 Sep 65

By culturing HeLa cells at stepwise increased oxygen tensions over a prolonged period of time (approximately 21 months) we selected a substrain capable of growing under 80% O2/19% N2/1% CO2, an oxygen level that is lethal to normal HeLa cells, adapted to 20% O2/79% N2/1% CO2. The 80% O2-adapted cells exhibited the following characteristics. At the ultrastructural level an abnormal mitochondrial morphology was observed: compared to normal cells, mitochondria of the hyperoxia-adapted cells exhibited a 3-fold larger mean profile area in sections and were slightly decreased in number; the relative mitochondrial volume was increased 2-fold, whereas the size of both cell types was the same. Mitochondrial matrix appeared less dense in the hyperoxia-adapted cells; no structural damage was detected. Compared to the 20% O2-adapted cells O2 consumption per cell was approximately 40% decreased in the 80% O2-adapted cells. Under hyperoxic conditions 20% O2-adapted and 80% O2-adapted cells exhibited very similar cyanide-resistant respiration rates (0.16 +/- 0.04 and 0.15 +/- 0.02 fmoles/cell/minute, respectively), suggesting that the increased O2 tolerance of the 80% O2-adapted cells was not due to a decreased cellular production of activated oxygen species at hyperoxia. Cellular levels of the enzymes directly involved in protection against activated oxygen species, i.e., superoxide dismutases, catalase, and glutathione peroxidase, were normal or slightly below normal in the 80% O2-adapted cells, implying that these enzymes were of no significance for the increased O2 tolerance. In addition, the specific activity of glucose-6-phosphate dehydrogenase, a key enzyme for cellular production of NADPH, was not related to the degree of O2 tolerance. Our results suggest that the increased O2 tolerance of the 80% O2-adapted cells is neither based on cellular properties controlling the formation or removal of intracellular activated oxygen species nor on the cellular capacity to repair or replace damaged cellular components. We speculate that the increased O2 tolerance is largely due to a genetically determined increased resistance of oxygen-sensitive cellular targets.
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PMID:Some characteristics of hyperoxia-adapted HeLa cells. A tissue culture model for cellular oxygen tolerance. 298 61

Hyperoxia inhibited concanavalin A stimulated O2- release (respiratory burst) of alveolar macrophages obtained by bronchoalveolar lavage from rats. After 36 h of normobaric 100% O2, a partial reversal (48%) of the inhibition was produced by addition of glucose. Since oxidant-induced, reversible NADPH depletion correlates with reversible inhibition of the respiratory burst, intracellular NADPH was assayed to determine whether irreversible inhibition of the respiratory burst was related to persistent changes in this metabolite. The cellular concentrations of ATP, glutathione, and ascorbate were also measured. After 36 h of hyperoxia, NADPH concentration in alveolar macrophages rose slightly while ATP and glutathione content remained at control levels. Ascorbate levels fell significantly but were not responsible for respiratory burst inhibition. Thus, irreversible loss of cellular function in hyperoxia is not due to persistent alterations in these metabolites. Significant amounts of both glutathione and ascorbate were found in extracellular fractions of lung washings, indicating high concentrations in the aqueous subphase in the lung fluid lining. There was no change in total content of these extracellular antioxidants following O2 exposure.
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PMID:Oxygen toxicity: loss of lung macrophage function without metabolite depletion. 301 77

Preexposure of rats to sublethal levels of hyperoxia or ozone reduces morbidity and mortality when the animals are subsequently exposed to lethal levels of either oxidant stress. Lung homogenates and isolated type II pneumocytes from rats exposed to these oxidant stresses demonstrate enhanced antioxidant enzyme activities. Antioxidant enzymes, superoxide dismutase, catalase, and glutathione peroxidase are responsible for the detoxification of partially reduced oxygen species, superoxide and hydrogen peroxide, to less reactive states. Potential pulmonary cellular loci of partially reduced oxygen include mitochondrial NADH dehydrogenase, endoplasmic reticulum-derived NADPH cytochrome c reductase, and cytosolic xanthine oxido reductase. Thus partially reduced oxygen species are hypothesized to mediate hyperoxia and ozone-induced pulmonary damage. This damage may be attenuated by enhanced intracellular antioxidant enzyme activities. Pharmacologic augmentation of pulmonary antioxidant enzymes may be accomplished via intratracheal or intravascular delivery of liposomes containing antioxidant enzymes. Rats pretreated with liposomes containing both superoxide dismutase and catalase, when subsequently exposed to lethal levels of hyperoxia, demonstrate enhanced survival compared with control animals or with animals treated with control liposomes or native antioxidant enzymes. Finally, knowledge obtained from in vitro investigations optimizing liposomal delivery to specific pulmonary cell types may further aid in reducing in vivo pulmonary damage to hyperoxia and ozone.
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PMID:Pulmonary metabolism of reactive oxygen species. 306 93

Preexposure to hypoxia increased survival and lung reduced glutathione-to-oxidized glutathione ratios (GSH/GSSG) and decreased pleural effusions in rats subsequently exposed to continuous hyperoxia. In addition, lungs from hypoxia-preexposed rats developed less acute edematous injury (decreased lung weight gains and lung lavage albumin concentrations) than lungs from normoxia-preexposed rats when isolated and perfused with hydrogen peroxide (H2O2) generated by xanthine oxidase (XO) or glucose oxidase (GO). In contrast, when perfused with elastase or exposed to a hydrostatic left atrial pressure challenge, lungs isolated from hypoxia-preexposed rats developed the same acute edematous injury as lungs from normoxia-preexposed rats. The mechanism by which hypoxia preexposure conferred protection against H2O2 appeared to depend on hexose monophosphate shunt (HMPS)-dependent increases in lung glutathione redox cycle activity. First, before perfusion with GO, lungs from hypoxia-preexposed rats had increased glutathione peroxidase and glucose 6-phosphate dehydrogenase (but not catalase or glutathione reductase) activities compared with lungs from normoxia-preexposed rats. Second, after perfusion with GO, lungs from hypoxia-preexposed rats had increased H2O2 reducing equivalents, as reflected by increased GSH/GSSG and NADPH/NADPH+, compared with lungs from normoxia-preexposed rats. Third, pretreatment of rats with an HMPS inhibitor, (6-aminonicotinamide) or a glutathione reductase inhibitor, [1,3-bis(2-chloroethyl)-1-nitrosourea] prevented hypoxia-conferred protection against H2O2-mediated acute edematous injury in isolated lungs. These findings suggest that increased detoxification of H2O2 by glutathione redox cycle and HMPS-dependent mechanisms contributes to tolerance to hyperoxia and resistance to H2O2 of lungs from hypoxia-preexposed rats.
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PMID:Hypoxia increases glutathione redox cycle and protects rat lungs against oxidants. 321 62

Further characteristics of an oxygen-tolerant variant of Chinese hamster ovary cells (CHO-99) capable of stable proliferation at 99% O2/1% CO2, and O2 level that is lethal to the parental line (CHO-20), are described. Previous work has revealed that CHO-99 cells have 2- to 4-fold increased activities of superoxide dismutases, catalase and glutathione peroxidase, and substantially increased relative volumes of mitochondria and peroxisomes. To document possible additional mechanisms of O2 tolerance we compared CHO-20 cells growing at 20% O2 (normoxia) and CHO-99 cells at 99% O2 (normobaric hyperoxia). We show the following: (1) the estimated total (oxidative and glycolytic) ATP production in CHO-99 cells was 36% decreased. ATP production through oxidative phosphorylation was 52% lower in CHO-99 cells, while the relative contribution from glycolysis was increased from 6% to 30%. The ATP content was 29% lower in CHO-99 cells, the adenylate energy charge being also significantly decreased, indicating that energy production through oxidative phosphorylation is compromised in CHO-99 cells. Cyanide-resistant respiration was 4-fold higher in CHO-99 cells, probably reflecting, at least partly, the increased peroxisomal activity in these cells. (2) The level of reduced glutathione was several fold increased in CHO-99 cells, oxidized glutathione being unaltered; (NADPH + NADP+) levels were elevated 2.7-fold, while the ratio of NADPH to NADP+ was increased almost two-fold. These changes were associated with a 50% increased metabolism of glucose through the hexose monophosphate pathway. (3) No evidence was obtained for an increased steady-state level of endogenous lipid peroxidation in CHO-99 cells, in spite of a 50% increased content of polyunsaturated fatty acids in the phospholipid fraction.
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PMID:Characterization of oxygen-tolerant Chinese hamster ovary cells. II. Energy metabolism and antioxidant status. 338 44

The effects of oxidative stress caused by hyperoxia or administration of the redox active compound diquat were studied in isolated hepatocytes, and the relative contribution of lipid peroxidation, glutathione (GSH) depletion, and NADPH oxidation to the cytotoxicity of active oxygen species was investigated. The redox cycling of diquat occurred primarily in the microsomal fraction since diquat was found not to penetrate into the mitochondria. Depletion of intracellular GSH by pretreatment of the animals with diethyl maleate promoted lipid peroxidation and sensitized the cells to oxidative stress. Diquat toxicity was also greatly enhanced when glutathione reductase was inhibited by pretreatment of the cells with 1,3-bis(2-chloroethyl)-1-nitrosourea. Despite extensive lipid peroxidation, loss of cell viability was not observed, with either hyperoxia or diquat, until the GSH level had fallen below approximately 6 nmol/10(6) cells. The iron chelator desferrioxamine provided complete protection against both diquat-induced lipid peroxidation and loss of cell viability. In contrast, the antioxidant alpha-tocopherol inhibited lipid peroxidation but provided only partial protection from toxicity. The hydroxyl radical scavenger alpha-keto-gamma-methiol butyric acid, finally, also provided partial protection against diquat toxicity but had no effect on lipid peroxidation. The results indicate that there is a critical GSH level above which cell death due to oxidative stress is not observed. As long as the glutathione peroxidase - glutathione reductase system is unaffected, even relatively low amounts of GSH can protect the cells by supporting glutathione peroxidase-mediated metabolism of H2O2 and lipid hydroperoxides.
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PMID:Effects of oxidative stress caused by hyperoxia and diquat. A study in isolated hepatocytes. 350 39

We have studied the influence of hyperoxia and ageing on the activities of NADPH-cytochrome c reductase and glutathione S-transferase in different rat organs. Lung glutathione S-transferase activity increases markedly in 5-day-old pups exposed to hyperoxia, as observed for the O2- scavenging enzyme, superoxide dismutase. The levels of NADPH-cytochrome c reductase increase as well but after a 3-day lag period. In the liver, there is a pronounced decrease of both activities in 24-month-old rats, but at 12 months the activity of glutathione S-transferase increases whereas that of NADPH cytochrome c reductase activity decreases with respect to 3 months. The pattern of variations with age of NADPH cytochrome c reductase is similar in liver and brain. However the behaviour of brain glutathione S-transferase parallels that of the liver enzyme only up to 12 months. Thereafter the brain activity is maintained at a high level. These observations open the possibility that the high glutathione S-transferase levels in the old rat brain might be involved in protection towards oxidative alterations during ageing.
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PMID:Variations due to hyperoxia and ageing in the activities of glutathione S-transferase and NADPH-cytochrome c reductase. 361 86

Isolated alveolar epithelial type II cells were exposed to paraquat and to hyperoxia by gas diffusion through the thin Teflon bottom of culture dishes. After exposure, type II cells were further incubated in the presence of labelled substrates to assess their capacity to synthesize lipids. Hyperoxia alone (90% O2; 5 h) had minor effects on lipid metabolism in the type II cells. At low paraquat concentrations (5 and 10 microM), hyperoxia enhanced the paraquat-induced decrease of [Me-14C]choline incorporation into phosphatidylcholines. The incorporation rates of [Me-14C]choline, [1-14C]palmitate, [1-14C]glucose and [1,3-3H]glycerol into various phospholipid classes and neutral lipids were decreased by paraquat, depending on the concentration and duration of the exposure. The incorporation of [1-14C]acetate into phosphatidylcholines, phosphatidylglycerols and neutral lipids appeared to be very sensitive to inactivation by paraquat. At 5 microM-paraquat the rate of [1-14C]acetate incorporation was decreased to 50% of the control values. The rate of [1-14C]palmitate incorporation into lipids was much less sensitive; it even increased at low paraquat concentrations. At 10 microM-paraquat both NADPH and ATP were significantly decreased. It is concluded that lipid synthesis in isolated alveolar type II cells is extremely sensitive to paraquat. At low concentrations of this herbicide, lipid synthesis, and particularly fatty acid synthesis, is decreased. The effects on lipid metabolism may be partly related to altered NADPH and ATP concentrations.
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PMID:Phospholipid synthesis in isolated alveolar type II cells exposed in vitro to paraquat and hyperoxia. 366 39

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