UMLS:C0242706 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

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

Blood acid-soluble sulfhydryl, but not glutathione (GSH), levels increased during the development of acute edematous lung injury in rats exposed to normobaric hyperoxia for 48 h or more. A relationship between increases in blood sulfhydryl levels, lung injury, and O2 metabolite generation during exposure to hyperoxia was suggested by two observations. First, increases in blood sulfhydryl levels occurred simultaneously with increases in lung oxidized glutathione (GSSG) levels and lung GSSG-to-GSH ratios (GSSG/GSH). Second, hyperoxia-induced increases in blood sulfhydryl levels, blood hematocrits, pleural effusion volumes, lung GSSG levels, and lung GSSG/GSH were decreased by pretreating rats with dimethylthiourea (DMTU), an O2 metabolite scavenger. Our findings indicate that exposure of rats to hyperoxia increases blood acid-soluble sulfhydryl levels in vivo and that increases in blood sulfhydryl levels may provide an accessible marker of increased oxidant exposure and/or oxidant-mediated lung injury.
...
PMID:Blood sulfhydryl level increases during hyperoxia: a marker of oxidant lung injury. 250 3

Cultured type II pneumocyte responses to in vitro normoxia (95% air:5% CO2) or hyperoxia (95% O2:5% CO2) were quantified. Normoxic culture (0 to 96 h) of rabbit type II cells resulted in enhanced cell-monolayer protein and DNA content. During this same time, cellular activities of superoxide dismutase (SOD), catalase, and glutathione peroxidase (GSH Px) decreased. Compared to cultures maintained in normoxia, hyperoxic exposure of cultures resulted in decreased cell-associated protein and DNA content. Exposure to hyperoxia also resulted in cytotoxicity as demonstrated by elevated cellular release of DNA, lactate dehydrogenase (LDH), and preincorporated 8-[14 C]adenine. Cellular catalase and GSH Px activities in hyperoxic cells decreased similarly to normoxic controls. In contrast, cellular SOD activity in hyperoxic cells decreased less than in normoxic cultures. Cellular SOD activity in hyperoxic cultures, when normalized for cellular protein, but not DNA, was greater than normoxic values after 24 to 96 h of exposure. Unlike the decrease in cellular antioxidant enzymes during normoxic and hyperoxic culture, cellular LDH activity increased during both these exposures. Cellular LDH activity in 24 to 96 h hyperoxia-exposed cells increased to a lesser extent than normoxic controls. The extent of depression in LDH activity was dependent on whether the activity was normalized for cellular protein or DNA. Type II pneumocytes, which normally undergo hyperplasia and hypertrophy during hyperoxia in vivo, exhibited oxygen sensitivity in vitro. Exposure of type II cells to hyperoxia in vitro resulted in alterations in cellular SOD and LDH activities, but recognition of such changes were dependent on whether enzymatic activities were normalized for cellular DNA or protein.
...
PMID:Responses of type II pneumocyte antioxidant enzymes to normoxic and hyperoxic culture. 250 12

1. During the development of D. pictus larvae (Amphibia) in normoxia, selenium (Se) GSH-Px increased whereas non-Se GSH-Px did not change. 2. Acclimation to 60 or 100% O2 did not change Se GSH-Px or non-Se GSH-Px. 3. Hyperoxia did not change tissue peroxidation (TBA-RS) confirming the good capacity of D. pictus tadpoles for O2-adaptation. 4. Since hyperoxic induction of catalase (CAT) has been previously described in D. pictus tadpoles, it is concluded that CAT is more important than both GSH-Px for the establishment of O2-adaptation. 5. Increases of Se GSH-Px, SOD and CAT, are probably important for adaptation to the change from aquatic to aerial environment during metamorphosis in normoxia. 6. Chronic exposure to 100% O2 enormously reduced the lung size of D. pictus larvae.
...
PMID:Hyperoxia decreases lung size of amphibian tadpoles without changing GSH-peroxidases or tissue peroxidation. 256 23

In addition to its participation in a variety of other biochemical reactions, glutathione (GSH) is a major antioxidant. It is regularly generated intracellularly from its oxidized form by glutathione reductase activity that is coupled with a series of interrelated reactions. Synthesis of GSH also takes place intracellularly by a two-step reaction, the first of which is catalyzed by rate-limiting gamma-glutamylcysteine synthetase activity. Intracellular substrates for GSH are provided both by direct amino acid transport and by a gamma-glutamyl transpeptidase reaction that salvages circulating GSH by coupling the gamma-glutamyl moiety to a suitable amino acid acceptor for transport into the cell. Although the liver is a net synthesizer of circulating GSH, organs such as the kidney salvage GSH through the gamma-glutamyl transpeptidase reaction. Intracellular GSH may be consumed by GSH transferase reactions that conjugate GSH with certain xenobiotics. Elevation of cellular GSH levels in cultured cells in response to hyperoxia or electrophilic agents such as diethylmaleate is coupled with an increase in activity of the Xc- transport system for the amino acids cystine and glutamate. Strategies may be developed for protection against oxidant injury by enhancement of transport systems for precursor amino acids of GSH or by providing substrate that circumvents feedback inhibition of GSH synthesis.
...
PMID:Regulation of cellular glutathione. 257 74

1. In order to clarify the relative role of catalase (CAT) and glutathione peroxidases (GSH-Px) at normal and high O2 tensions, Rana perezi frogs were chronically treated with aminotriazole (AT), hyperoxia, or both. 2. A 100% survival was observed with both treatments. Hyperoxia increased liver catalase and kidney TBA-RS and decreased GSH-Px. 3. AT caused quantitatively higher alterations than hyperoxia in both organs: CAT was depleted, TBA-RS increased (114% in kidney) and GSH-Px decreased. 4. It is concluded that in Rana perezi (a) CAT, in spite of its much higher KM and Vmax in relation to GSH-Px, is needed to avoid oxidative stress even in normoxia; (b) normoxic tissues have significative amounts of H2O2; (c) GSH-Px does not compensate the lack of CAT.
...
PMID:Catalase is needed to avoid tissue peroxidation in Rana perezi in normoxia. 257 77

A protective effect of butyrate against hyperoxia was found with adult rat pulmonary artery smooth muscle cells. Butyrate (5mM) when added just prior to the hyperoxic exposure (95%) markedly decreased lactate dehydrogenase release from cells during 68 hours of exposure (22% release with butyrate versus 98% without). The uptake and reduction of a tetrazolium compound as another index of cell viability also showed similar improvement with butyrate. Butyrate was associated with a striking increase of catalase to three times the control in the air exposed group while GSH content and the activities of superoxide dismutase and glutathione peroxidase were not significantly changed. In the groups exposed to hyperoxia alone, both enzyme activities were decreased compared to the air exposed controls. When butyrate was present with hyperoxia, the superoxide dismutase was maintained closer to the air exposed control values and the catalase activity remained nearly twice as high as the air exposed control cells. These results suggest that butyrate protects rat pulmonary artery smooth muscle cells from hyperoxia by increasing catalase activity which may help to preserve superoxide dismutase activity. This may be a good model to determine the biological significance of catalase and its interrelationships with other antioxidant systems within the cell.
...
PMID:Butyrate increases catalase activity and protects rat pulmonary artery smooth muscle cells against hyperoxia. 259 Jan 95

We previously reported that pretreatment with endotoxin significantly reduced acute pulmonary O2 toxicity in lambs (J. Appl. Physiol. 65: 1579-1585, 1988). One of endotoxin's many effects is to inhibit cytochrome P-450 mono-oxygenation reactions, which are believed to produce toxic O2 species. Therefore, one possible explanation for endotoxin's beneficial effect is that it inhibited P-450-mediated O2 radical production during hyperoxia. To test this hypothesis, we administered a single dose of cimetidine, a noncompetitive inhibitor of P-450 activity, to nine lambs before continuous exposure to greater than 95% O2. Compared with six control O2-exposed lambs, the cimetidine-treated O2-exposed lambs maintained normal gas exchange for a longer period of time (P less than 0.01), accumulated lung water at a slower rate (P less than 0.01), and had normal microvascular permeability after 72 h of O2 exposure. Postmortem levels of antioxidant enzymes in blood-free lung homogenate were not increased in cimetidine-treated lambs. However, the levels of oxidized glutathione were significantly lower in cimetidine-treated lambs, and the ratio of reduced to oxidized glutathione concentrations (GSH/GSSG ratio) was sevenfold higher than the ratio measured in control O2-exposed lambs (P less than 0.001). In four lambs, pretreatment with ranitidine (a drug chemically related to cimetidine but without P-450 inhibitory activity) had no effect either on the time course of O2 injury or on postmortem antioxidants. Microsomes were isolated from blood-free lung of all study animals and P-450 activity of the form 2 isozyme was measured.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Cimetidine reduces hyperoxic lung injury in lambs. 260 66

Exposure of rats to 100% O2 at high pressure (greater than 2.0 ATA) results in generalized convulsions and death within several hours. The tripeptide, glutathione, has been shown to protect rats exposed to hyperbaric hyperoxia with delayed onset of seizures and prolonged survival. To investigate the hypothesis that glutathione exerts its protective effects via the glutathione redox cycle, we injected selenium-deficient rats and their selenium-supplemented controls with either glutathione (1 mmol/kg) or an equivolume of saline before exposure to 100% O2 at 4 ATA. Selenium-deficient rats exhibit marked reduction in liver glutathione peroxidase activity (GSH-Px). Glutathione administration significantly delayed both the onset of seizures and time to death in the control animals. In selenium-deficient rats, however, glutathione administration was not protective, having no significant effects on time to seizure or time to death. We also measured changes in glutathione concentrations in lung, liver, and brain of these same groups of animals exposed either to hyperbaric hyperoxia or to room air. In control rats, lung and brain glutathione concentrations did not change with the hyperbaric exposure regardless of glutathione pretreatment status, but hepatic glutathione concentration declined significantly during the exposure when glutathione was not supplied. If these animals were pretreated with glutathione, the decline in hepatic glutathione concentrations did not occur. In selenium-deficient rats, the hyperbaric exposure did not result in changes in lung, brain, or liver glutathione concentrations either in the glutathione-pretreated or in the saline-pretreated animals. Exogenous GSH administration does not protect selenium-deficient rats from hyperbaric hyperoxia.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Effects of selenium deficiency on glutathione-induced protection from hyperbaric hyperoxia in rat. 261 Feb 68

Diethyl maleate (DEM, 0.025-0.10 mM) increased glutathione (GSH) levels in calf pulmonary artery endothelial cells up to fivefold in 12-24 h of incubation. Parallel increases occurred in the rates of uptake of cystine and glutamate. The DEM-mediated increases in both GSH levels and glutamate-cystine uptake were inhibited by cycloheximide and actinomycin D, indicating a dependency on protein and RNA synthesis. The stimulatory effects of DEM on amino acid uptake and GSH levels were greater than those in endothelial cells exposed to 80% O2 for 24 h. The effect of hyperoxia on cellular transport processes was also less specific than that of DEM. Although the increase in glutamate uptake produced by hyperoxia appeared to be under the regulation of protein synthesis, the relationship with elevated GSH in the presence of hyperoxia was less clear because of elevation of control cellular GSH by cycloheximide or actinomycin D alone. Inhibition of GSH synthesis by buthionine sulfoximine also stimulated cystine and glutamate uptake. We conclude that elevation of endothelial intracellular GSH by both DEM and hyperoxia is associated with and may be produced by enhanced uptake of precursor amino acids; the effect of DEM is more pronounced and more specific than that of hyperoxia.
...
PMID:Increase in endothelial cell glutathione and precursor amino acid uptake by diethyl maleate and hyperoxia. 280 55

We have previously found that exposure of pulmonary artery endothelial cells to hyperoxia or low concentrations of diethyl maleate (DEM) results in elevation of both cellular glutathione (GSH) and uptakes of glutamate and cystine. The present study confirms that this elevation occurs for a variety of lung cells (bovine pulmonary artery endothelial and smooth muscle cells and rat lung fibroblast and epithelial-like cells) but not for human, rat, and chicken erythrocytes. In fact, human and rat erythrocyte GSH levels were reduced substantially at DEM concentrations from 0.05 to 0.5 mM, whereas the GSH level of chicken erythrocytes was almost totally eliminated by 0.05 mM DEM. Also, all erythrocytes failed to accumulate measurable amounts of radioactive glutamate or cystine. The findings suggest the presence of different mechanisms for the regulation of cellular GSH in lung cells from those of erythrocytes. They are consistent with a requirement for a cystine-glutamate transporter and transcriptional and translational events for the elevation of cellular GSH in response to hyperoxia or low levels of DEM in the lung cells.
...
PMID:Erythrocytes fail to induce glutathione in response to diethyl maleate or hyperoxia. 280 56

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>