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 total Mg2+-ATPase and Na+, K+-ATPase activity was studied in the fractions of "400 g X for 20 min" and "900 g X for 30 min" conditionally called the fraction of the external cellular membranes and total fraction of mitochondria. The subcellular fractions were isolated from great hemispheres and stem part of the rat brain. The brain of control animals and those during a severe spasmodic attact induced by the oxygen action at a pressure of 6 ati was studied. The total ATPase activity is established to be practically the same in the studied brain areas and unchanged with hyperoxia. Hyperoxia accompanying by convulsions results in an increase in the activity of Mg2+-ATPase and in a decrease in that of Na+, K+-ATPase both in the cerebral cortex and the stem part. The authors suppose that the decrease in the enzyme activity may occur due to an inhibitory effect on it of the lipids reoxidation products formed in the brain with hyperoxia.
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PMID:[ATPase activity of subcellular rat brain fractions following hyperoxia]. 13 79

Previous work has shown that irrespective of the route of exposure methyl isocyanate (MIC) caused acute lactic acidosis in rats (Jeevaratnam et al., Arch. Environ. Contam. Toxicol. 19, 314-319, 1990) and the hypoxia was of stagnant type due to tissue hypoperfusion resulting from hypovolemic hypotension in rabbits administered MIC subcutaneously (Jeevarathinam et al., Toxicology 51, 223-240, 1988). The present study was designed to investigate whether MIC could induce histotoxic hyperoxia through its effects on mitochondrial respiration. Male Wistar rats were used for liver mitochondrial and submitochondrial particle (SMP) preparation. Addition of MIC to tightly coupled mitochondria in vitro resulted in stimulation of state 4 respiration, abolition of respiratory control, decrease in ADP/O ratio, and inhibition of state 3 oxidation. The oxidation of NAD(+)-linked substrates (glutamate + malate) was more sensitive (five- to sixfold) to the inhibitory action of MIC than succinate while cytochrome oxidase remained unaffected. MIC induced twofold delay in the onset of anerobiosis, and cytochrome b reduction in SMP with NADH in vitro confirms inhibition of electron transport at complex I region. MIC also stimulated the ATPase activity in tightly coupled mitochondria while lipid peroxidation remained unaffected. As its hydrolysis products, methylamine and N,N'-dimethylurea failed to elicit any change in vitro; these effects reveal that MIC per se acts as an inhibitor of electron transport and a weak uncoupler. Administration of MIC sc at lethal dose caused a similar change only with NAD(+)-linked substrates, reflecting impairment of mitochondrial respiration at complex I region and thereby induction of histotoxic hypoxia in vivo.
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PMID:In vitro and in vivo effect of methyl isocyanate on rat liver mitochondrial respiration. 147 Nov 48

A major function of the alveolar epithelium is to keep the airspace free of fluid and preserve gas exchange. Since Na-K-ATPase is believed to be important in this process, we hypothesized that Na-K-ATPase in the rat lung would increase in response to acute lung injury with pulmonary edema. Na-K-ATPase localization, mRNA expression, and protein levels were determined in hyperoxic lung injury. Adult male rats were exposed to greater than 97% oxygen for 60 h followed by recovery in room air. At 60 h of hyperoxia, the wet-to-dry lung weights increased, consistent with edema. Within the alveolar capillary region, the sodium pump remained localized to the type II cell basolateral membrane by immunocytochemistry. By Northern blot analysis, the level of total lung mRNA expression of the alpha 1- and beta-subunits of Na-K-ATPase increased three- to fourfold during hyperoxia compared with unexposed rats. Total lung Na-K-ATPase membrane protein, visualized with a Western blot technique, appeared to increase by 24 h of hyperoxic insult when compared with levels in unexposed animals. The increase in sodium pump gene expression that occurs during hyperoxic insult, followed by an increase in sodium pump membrane protein, suggests that type II cells increase their Na-K-ATPase synthesis as an early response to pulmonary edema and/or hyperoxia.
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PMID:Upregulation of rat lung Na-K-ATPase during hyperoxic injury. 165 77

To evaluate the relative contributions of three possible mechanisms that can be advanced to explain the observation that hyperoxia decreases serotonin uptake by endothelial cells, we examined the effect of high O2 tensions on Na+-K+-ATPase activity, ATP content, and plasma membrane fluidity in cultured endothelial cells. Confluent monolayers of pulmonary artery and aortic endothelial cells were exposed to 95% O2 (hyperoxia) or 20% O2 (controls) in 5% CO2 at 1 ATA for 4-42 h. Exposure to high O2 tensions had no effect on Na+-K+-ATPase activity or ATP content in pulmonary artery or aortic endothelial cells in culture. However, hyperoxia decreased the fluidity of the plasma membrane of pulmonary artery and aortic endothelial cells in culture, and the time course for the decrease in fluidity parallels that of the hyperoxic inhibition of serotonin transport. These results indicate that hyperoxia decreases fluidity in the hydrophobic core of the plasma membranes of cultured endothelial cells. Such decreases in plasma membrane fluidity may be responsible for hyperoxia-induced alterations in membrane function including decreases in transmembrane transport of amines.
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PMID:Hyperoxia reduces plasma membrane fluidity: a mechanism for endothelial cell dysfunction. 300 28

Sodium transport across the lung epithelium is predominantly effected by apical amiloride-sensitive Na+ channels and basolaterally located ouabain-sensitive Na,K-ATPases. Previously, we reported that subacute hyperoxia caused an increase in active Na+ transport in rat lungs paralleling Na,K-ATPase upregulation in alveolar Type 2 cells isolated from the same lungs. In the present study we set out to quantify the amiloride-sensitive Na+ flux and ouabain-sensitive active Na+ transport in the isolated-perfused, fluid-filled lung model from rats exposed to 85% O2 for 7 d compared with normoxic control rats. We found increased transpulmonary albumin flux and permeability to small solutes (Na+ and mannitol) in hyperoxic rat lungs compared with controls. Amiloride (10(-5) M) instilled into rat airspaces inhibited active Na+ transport by approximately 62% in control rat lungs and by approximately 87% in lungs from rats exposed to hyperoxia, without further changing permeability for Na+ and mannitol. Ouabain (10(-5)M) perfused through the pulmonary circulation decreased active Na+ transport by approximately 40% in normal rat lungs and by approximately 52% in lungs from rats exposed to hyperoxia. We conclude that active Na+ transport and edema clearance are increased in the subacute hyperoxic lung injury in rats, caused in part by the upregulation of amiloride-sensitive apical Na+ channels and alveolar epithelial Na,K-ATPases. Conceivably, the upregulation of alveolar epithelial Na+ channels and Na,K-ATPases protects against the effects of lung injury in this model by contributing to effective edema clearance.
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PMID:Mechanisms of lung liquid clearance during hyperoxia in isolated rat lungs. 773 9

The rat erythrocytes' Na, K-ATPase activity was found to drop under the effects of five various stresses: immobilisation, hypothermia, hyperoxia, physical strain, and physical strain against the background of fasting. An endogenous digoxin-like inhibiting agent(s) acting on the Na, K-ATPase seems to appear in the blood plasma of the animals under stress. The suggestion is corroborated by the fact that albumin-less supernatants of the stressed rats' blood plasma are able to inhibit the Na, K-ATPase in the erythrocytes of the control animals.
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PMID:[The dynamics and mechanism of changes in the erythrocyte Na, K-ATPase activity of rats under the action of different types of stressors]. 816 17

Active Na+ transport and lung edema clearance were studied in a model of lung injury caused by sublethal oxygen exposure. Rats exposed to 85% O2 for 7 days were studied at 0, 7, 14, and 30 days after removal from the hyperoxic chamber and compared with room air controls. In the isolated-perfused, fluid-filled rat lung, albumin flux from the perfusate into the air spaces increased after oxygen exposure and returned to control values after 7 days of recovery. However, permeability to small solutes (Na+ and mannitol) normalized only after 30 days of recovery from hyperoxia. Active Na+ transport increased immediately after oxygen exposure and returned to control values 7 days after removal from hyperoxic chamber. Na-K-adenosinetriphosphatase (ATPase) activity, and protein expression in alveolar epithelial type II cells obtained at the end of the isolated lung experiments increased significantly after the oxygen exposure compared with controls in association with the increased active Na+ transport. We conclude that active Na+ transport and lung liquid clearance are increased in the subacute hyperoxic phase of lung injury in rats, due in part to the upregulation of alveolar epithelial Na-K-ATPases. Conceivably, this behavior protects against the effects of lung injury by allowing the injured lung to clear edema more effectively. Accordingly, this upregulation may be targeted as a strategy to diminish edema in patients with lung injury.
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PMID:Active sodium transport and alveolar epithelial Na-K-ATPase increase during subacute hyperoxia in rats. 820 51

By participating in glutathione (GSH) synthesis, gamma-glutamyl transpeptidase (GGT) influences the GSH redox cycle, which is a major contributor in protecting against reactive oxygen metabolites. This study determined the effect of prolonged exposure of neonatal rats to > 98% oxygen on expression of GGT and on GSH metabolism. Lungs of neonatal rats chronically exposed to hyperoxia had increased expression of GGT mRNA, resulting in significantly higher GGT protein levels and enzyme activity than in lungs of animals raised in room air. Hyperoxia also upregulated glucose-6-phosphate dehydrogenase, but Na-K-ATPase activity was not changed. GGT mRNA, protein level, and enzyme activity returned to control levels after recovery in room air for 3 days. Levels of GSH, glutathione disulfide, and protein-bound GSH (S-glutathiolated protein) rose with hyperoxia and fell during recovery. S-glutathiolation is likely a mechanism for protection and a regulatory modification of protein sulfhydryl groups. Hyperoxia-induced upregulation of GGT and the concomitant increase in protein S-glutathiolation appear to be additional components fundamental in protecting the lung against oxidative injury.
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PMID:Hyperoxia enhances expression of gamma-glutamyl transpeptidase and increases protein S-glutathiolation in rat lung. 877 34

Alveolar fluid is resorbed using active Na+ transport primarily through basolateral sodium-potassium-adenosinetriphosphatase (Na-K-ATPase) and apical Na+ channels that are particularly dense on the alveolar type II (ATII) epithelial cells. During lung injury with pulmonary edema, continued or accelerated Na+ and fluid resorption is critical for a favorable outcome. However, little is known of how ATII cell Na+ transport is affected during injury. These experiments examined the effects of acute lung injury on ATII cell Na-K-ATPase activity and expression using an established model of rats exposed to 100% O(2) for 60 h. Na-K-ATPase activity of ATII cells isolated immediately after exposure was assessed by ouabain-sensitive (86)Rb+ uptake in intact cells and by ouabain-sensitive P(i) production by cell membranes. In the presence of 1 mM ouabain, ouabain-sensitive Rb+ uptake was not different between normoxic and hyperoxic cells, but the apparent Na-K-ATPase maximal velocity (Vmax) of hyperoxic cell membranes was 75 +/- 8% of normoxic membranes (P < 0.05). On Western blots of ATII cell membranes, alpha1-subunit protein significantly decreased with hyperoxia (35 +/- 9% of normoxia; P < 0.05), whereas the amounts of the beta-subunit were unchanged (P > 0.05). On Northern blots of ATII cell total RNA, steady-state levels of both the alpha1- and beta1-subunit mRNA increased after hyperoxia (alpha1 = 2.5 +/- 1.3-fold; beta1 = 4.6 +/- 2.5-fold). Thus despite hyperoxic decreases in Na-K-ATPase Vmax and the amount of alpha1-protein, Rb+ uptake by Na-K-ATPase in intact cells was unchanged. The mRNA levels, protein amounts, and enzyme activity did not respond in parallel to hyperoxic injury, and the activity in intact cells correlated best with the amounts of the beta-subunit, the limiting component in de novo pump assembly in many tissues.
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PMID:Effects of hyperoxia on type II cell Na-K-ATPase function and expression. 912 12

Active Na+ transport by the alveolar epithelium keeps alveoli relatively dry. Hyperoxia increases epithelial permeability, resulting in pulmonary edema. We sought to determine whether active Na+ resorption from the air spaces and Na-K-ATPase activity increased in rats exposed to > 95% O2 for 60 h. The permeability x surface area products for unidirectional resorption of alveolar [14C]sucrose (PSsucrose) and 22Na+ (PSNa+) were measured in isolated, perfused rat lungs immediately after hyperoxia and after 3 and 7 days of recovery in room air. At 60 h of hyperoxia, the mean PSsucrose and PSNa+ increased from 6.71 +/- 0.8 x 10(-5) to 12.6 +/- 1.6 x 10(-5) cm3/s (P = 0.029) and from 23.6 +/- 1.1 x 10(-5) to 31.0 +/- 1.6 x 10(-5) cm3/s (P < 0.008), respectively. However, the values in individual rats ranged widely from no change to nearly a fourfold increase. Subgroup analysis revealed that benzamil- or amiloride-sensitive (transcellular) PSNa+ was significantly reduced in the exposed lungs with normal PSsucrose but was maintained in the lungs with high PSsucrose. By day 3 of recovery, mean Na+ and sucrose fluxes returned to values similar to control. Na-K-ATPase membrane hydrolytic maximal velocity (Vmax) activity fell significantly immediately after hyperoxic exposure but recovered to normal values by day 3 of recovery. The Na-K-ATPase beta 1-subunit antigenic signal did not significantly change, whereas the alpha 1-subunit levels increased during recovery. In summary, there was a heterogeneous response of different rats to acute hyperoxia. Hyperoxia led to complex, nonparallel changes in Na+ pump antigenic protein, hydrolytic activity, and unidirectional active Na+ resorption. Active Na+ transport was differentially affected, depending on degree of injury, but permeability and transport normalized by day 3 of recovery.
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PMID:Hyperoxic effects on alveolar sodium resorption and lung Na-K-ATPase. 943 74


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