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)

The effect of hyperoxia (1-14 days, 85% O2) on rat alveolar macrophage and alveolar type II cell oxidant and antioxidant characteristics was investigated. Unstimulated control macrophages (2 h ex vivo) released hydrogen peroxide at a rate of 3.5 +/- 1.3 nmol/min mg protein-1, which was a cyanide-sensitive process. H2O2 release from alveolar macrophages decreased slightly but not significantly after 1 day in hyperoxia and increased significantly after 3 days (180%, p less than .05) and 14 days (380%, p less than .01). When H2O2 release was expressed as nmol from total macrophages per animal, the increase after 14 days in hyperoxia was 760%. H2O2 generation by hyperoxic macrophages was cyanide resistant, indicating the involvement of active NADPH oxidase. In both control and hyperoxic macrophages H2O2 release could be significantly stimulated with phorbol myristate acetate (PMA). Comparisons of H2O2 release by freshly isolated alveolar macrophages and alveolar type II cells must be cautiously interpreted because some cell functions may change during the isolation procedure. Freshly isolated (6 h ex vivo) control alveolar type II cells were found to generate H2O2 at a rate of 0.26 +/- 0.05 nmol/min mg protein-1. In type II cells H2O2 release, calculated as nmol/mg protein, decreased during the first 7 days of hyperoxia to 10% (p less than .01) of the control value and then returned back up to the control level after 14 days. A similar decrease was observed if H2O2 release was calculated as nmol/cell number. H2O2 release from control and hyperoxic type II cells was cyanide sensitive. The decrease in H2O2 release in type II cells was associated with cell membrane injury (as assessed by electron microscopy), while biochemical markers of cellular injury (trypan blue exclusion and cellular high-energy phosphates ATP, ADP) were unchanged. The ability of type II cells to scavenge extracellular H2O2 did not change in acute hyperoxia, but it increased significantly during the second week in hyperoxia. These results indicate that macrophages but not type II cells are stimulated to produce H2O2 during prolonged exposure to hyperoxia.
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PMID:Hydrogen peroxide release from alveolar macrophages and alveolar type II cells during adaptation to hyperoxia in vivo. 139 11

1) That non-invasive NMR and optical methods can a) quantify the work stress on mitochondria for ATP production, and b) indicate the tissue O2 tension in the capillary bed that is responsible for the rate of radical generation. 2) That free radical damage to mitochondrial function can be quantified by reciprocal plots of inverse slope giving the extrapolated Vm of mitochondria. 3) That a particular genetically deficient individual requiring high dosages of menadione has survived over 9 years. 4) That mitochondrial deficiency leads to an exercise hyperoxia.
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PMID:Instabilities of metabolic regulations in aging. 145 Jun 6

An in vitro model of alveolar epithelial oxidant injury was developed based on exposure to hyperoxia of cultured guinea pig type II pneumocytes using a biphasic cell culture system in aerobiosis. The present study investigates the roles of intracellular antioxidant enzymes and of glutathione in providing protection against hyperoxia. A 2-day type II cell culture in normoxia was associated with a significant decrease in protein, catalase, and Cu-Zn SOD cell content, whereas ATP cell content, Mn-SOD, and glutathione peroxidase (GPx) activities did not change and glutathione cell content significantly increased. Exposure of type II cells to hyperoxia did not induce significant changes in cell content in protein, SOD, catalase, GPx, or glutathione cell content when compared to control cells (exposed to normoxia). With ATP cell content expressed as a cell injury index (CII), type II cell injury was found to increase with increasing O2 concentrations. Indeed, a 2-day 50% O2 and 95% O2 exposure resulted in a CII of -7.5 +/- 6.2% and 17.9 +/- 5.9%, respectively, LDH release by type II cells was not significantly increased after hypoxic exposure. Cell injury effects of hyperoxia did not correlate with the endogenous antioxidant enzyme activities (SOD, Mn-SOD, catalase). In marked contrast, there was a significant correlation between the CII and total glutathione content of type II cells (p < .01). This correlation was largely due to the close relationship between CII and reduced glutathione. Hyperoxic induced cell injury (as demonstrated by CII > 0) was clearly associated with significantly lower intracellular glutathione level when compared to experiments without hyperoxia induced cell injury (CII < 0). In addition, in the presence of buthionine sulfoximine (BSO), the ability of type II cells to synthetize new glutathione was severely impaired, whereas ATP cell content and cell antioxidant enzyme activities did not change. As a consequence, the reduction of intracellular glutathione significantly increased the susceptibility of cells to hyperoxia injury (p < .05). The results strongly support the hypothesis that the regulation of glutathione levels is an important mechanism in protecting hyperoxia-induced type II cell injury.
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PMID:In vitro effects of hyperoxia on alveolar type II pneumocytes: inhibition of glutathione synthesis increases hyperoxic cell injury. 146 13

The causes of the adenosine monophosphate (AMP) deamination increase in rat brain mitochondria under conditions of hyperoxia, hypoxia and cold stress were studied. Data from the inhibitory analysis suggest that the increased intensity of AMP deamination under hypoxia is conditioned by the alterations in the substrate specificity of type A monoamine oxidase which acquires the ability to deaminate AMP. The enhancement of AMP deamination under hyperoxia and cold stress is due to the activation of true AMP deaminase in the mitochondrial fraction. The cytoplasmic AMP deaminase activity remains unchanged thereby. The effects of the AMP deaminase specific effectors, ATP and inorganic phosphate, were investigated.
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PMID:[Deamination of adenosine monophosphate in the rat brain in hyperoxia, hypoxia, and cold stress]. 152 39

We have recently shown that exposure of Chinese hamster ovary (CHO) cells to a toxic dose of normobaric hyperoxia (98% O2 for 3 days) caused a disturbance of cellular energy metabolism, that is, respiratory failure followed by stimulation of glycolytic activity and a net depletion of ATP. Respiratory failure was correlated with a selective inactivation of three mitochondrial enzymes, that is, partial inactivation of NADH dehydrogenase and virtually complete inactivation of succinate and alpha-ketoglutarate dehydrogenase activities (Schoonen et al., 1990). To elucidate the biochemical basis of resistance to hyperoxia in a previously described oxygen-resistant substrain of Chinese hamster ovary (CHO) cells, we compared the resistant cells with wildtype CHO cells with respect to several key parameters of oxidative and glycolytic energy metabolism. The two cell types were critically different in that the succinate and alpha-ketoglutarate dehydrogenases of the oxygen-resistant cells were relatively resistant to inactivation by hyperoxia, which may at least partly explain their enhanced capacity to respire and survive under hyperoxic conditions. Although the biochemical basis for the observed enzyme resistance to hyperoxic inactivation remains to be elucidated, the present data underscore the importance of succinate and alpha-ketoglutarate dehydrogenases as critical targets in hyperoxic killing of wildtype CHO cells.
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PMID:Characterization of oxygen-resistant Chinese hamster ovary cells. III. Relative resistance of succinate and alpha-ketoglutarate dehydrogenases to hyperoxic inactivation. 201 73

Cellular intoxication by elevated concentrations of O2 may be considered as a model for accelerated cellular aging processes resulting from excessive free radical production by normal metabolic pathways. We describe here that exposure of HeLa cell cultures to 80% O2 for 2 days causes progressive growth inhibition and loss of reproductive capacity. This intoxication was correlated with inhibition of cellular O2 consumption and inactivation of 3 mitochondrial flavoproteins, i.e., partial inactivation of NADH and succinate dehydrogenases and total inactivation of alpha-ketoglutarate dehydrogenase. As alpha-ketoglutarate dehydrogenase controls the influx of glutamine/glutamate into the Krebs cycle, which is the major pathway for oxidative ATP generation in HeLa cells, the inactivation of alpha-ketoglutarate dehydrogenase was expectedly correlated with a net fall in glutamine/glutamate utilization. Furthermore, a simultaneous increase in glucose consumption and lactate production was observed, indicating that the cellular response to respiratory failure is to generate more ATP from glycolysis. In spite of this response, extensive depletion of ATP was observed. Thus, hyperoxia-induced growth inhibition and loss of clonogenicity seem to be due primarily to an impairment of mitochondrial energy metabolism resulting from inactivation of SH-group-containing flavoprotein enzymes localized at or near the inner mitochondrial membrane. These observations may be relevant for theories implicating loss of mitochondrial function as a prime factor in the aging process.
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PMID:Hyperoxia-induced clonogenic killing of HeLa cells associated with respiratory failure and selective inactivation of Krebs cycle enzymes. 223 21

Recent discoveries have shown that venous diseases have a multifactorial etiology. One of the factors which is definitely involved in this pathologic process is the change in the concentration of oxygen. An increase in the concentration of oxygen, hyperoxia, or reoxygenation following hypoxia, damages the tissues by stepping up the production of free radicals. In addition, a reduction in oxygen concentration, or hypoxia, is also damaging, probably through a reduction in ATP synthesis. From a therapeutic standpoint, the veins, and more particularly the endothelium, must be protected against the impact on the tissue of these changes in oxygen concentration. In this study, the effects of Ginkor Fort were tested on cultured endothelial cells subjected to varying oxygen pressures. The results show that Ginkor Fort can provide good protection of endothelial cells against hyperoxia and hypoxia-reoxygenation. These beneficial effects are probably due to the presence of flavonoids in the Ginko biloba extract; these flavonoids have an anti-oxidant effect. In addition, this substance also protects the cells against hypoxia, possibly by increasing the availability of oxygen for ATP synthesis. This dual protective effect, which is produced by two different mechanisms, may account for the wide spectrum of Ginkor Fort in its use in venous diseases.
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PMID:[Behavior of human endothelial cells in hyperoxia and hypoxia: effect of Ginkor Fort]. 223 46

The Fischer rat is known for its susceptibility to develop liver necrosis when challenged with paraquat (Smith et al., J. Pharmacol. Exp. Ther. 235: 172-177, 1985). We postulated that other organs, specifically the lung, may also be more susceptible to injury and examined whether lungs from Fischer (F) rats were injured more easily when challenged with active oxygen species than Sprague-Dawley (SD) rat lungs. We aimed to investigate whether increased susceptibility to oxidant injury was related to differences in lung antioxidant defenses. Perfused lungs from both rat strains were challenged by addition of H2O2 to the perfusate or by short-term hyperoxic ventilation. To assess nonoxidant modes of lung injury, we examined lung responses after exposure to protamine sulfate or neutrophil elastase. Intravascular H2O2 or 3 h in vitro hyperoxia caused lung edema in F but not SD rats, and elastase injured F rat lungs more than the lungs from SD rats. Protamine, however, injured the lungs from both strains to a similar degree. Catalase, but not superoxide dismutase or allopurinol, protected F rat lungs against edema, resulting from 3 h in vitro hyperoxia. The lung homogenate levels for reduced glutathione or conjugated dienes and the activities of lung tissue catalase, glutathione peroxidase, and cytochrome P-450 were not different between the two strains. Lung tissue ATP levels, however, were lower in F than in SD rats. Although the F rat strain appears to have an altered oxidant-antioxidant defense balance, the exact cause of the greater susceptibility to oxidant stress of the F rat strain remains elusive.
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PMID:Lung injury in Fischer but not Sprague-Dawley rats after short-term hyperoxia. 226 Jun 76

Continuous exposure of Chinese hamster ovary (CHO) cells to an atmosphere of 98% O2, 2% CO2 (normobaric hyperoxia) leads within a period of several days to cytostasis and clonogenic cell death. Here we report respiratory failure as an important early symptom of oxygen intoxication in CHO cells, resulting in a more than 80% inhibition of oxygen consumption within 3 days of hyperoxic exposure. This inhibition appeared to be correlated with selective inactivation of three mitochondrial key enzymes, NADH dehydrogenase, succinate dehydrogenase, and alpha-ketoglutarate dehydrogenase. The latter enzyme controls the influx of glutamate into the Krebs cycle and is particularly critical for oxidative ATP generation in most cultured cells, which depends on exogenous glutamine rather than glucose as a carbon source. As expected, the inactivation of alpha-ketoglutarate dehydrogenase was correlated with a fall in cellular glutamine utilization, which became apparent from the first day of hyperoxic exposure. Thereafter, glucose utilization and lactate excretion started to increase, up to 3-fold, indicating a cellular response to respiratory failure aimed at increased ATP generation from glycolysis. However, in spite of this response, the cellular ATP level progressively decreased, up to 2.5-fold. Thus, killing of CHO cells by normobaric hyperoxia seems to be due to a severe disturbance of mitochondrial metabolism eventually leading to a depletion of cellular ATP pools.
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PMID:Respiratory failure and stimulation of glycolysis in Chinese hamster ovary cells exposed to normobaric hyperoxia. 235 58

Cell death by oxidative stress has been proposed to be based on suicidal NAD depletion, typically followed by ATP depletion, caused by the NAD-consuming enzyme poly(ADP)ribose polymerase, which becomes activated by the presence of excessive DNA-strand breaks. In this study NAD+, NADH and ATP levels as well as DNA-strand breaks (assayed by alkaline elution) were determined in Chinese hamster ovary (CHO) cells treated with either H2O2 or hyperoxia to a level of more than 80% clonogenic cell killing. With H2O2 extensive DNA damage and NAD depletion were observed, while at a higher H2O2 dosage ATP also became depleted. In agreement with results of others, the poly(ADP)ribose polymerase inhibitor 3-aminobenzamide completely prevented NAD depletion. However, both H2O2-induced ATP depletion and cell killing were unaffected by the inhibitor, suggesting that ATP depletion may be a more critical factor than NAD depletion in H2O2-induced killing of CHO cells. With hyperoxia, only moderate DNA damage (2 X background) and no NAD depletion were observed, whereas ATP became largely (70%) depleted. We conclude that (1) there is no direct relation between ATP and NAD depletion in CHO cells subjected to toxic doses of H2O2 or hyperoxia; (2) H2O2-induced NAD depletion is not by itself sufficient to kill CHO cells; (3) killing of CHO cells by hyperoxia is not due to NAD depletion, but may be due to depletion of ATP.
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PMID:Effects of lethal exposure to hyperoxia and to hydrogen peroxide on NAD(H) and ATP pools in Chinese hamster ovary cells. 277 Jul 61


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