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Query: UMLS:C0242706 (
hyperoxia
)
5,219
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Exposure to
hyperoxia
causes loss of alveolar macrophage cell function. Toxicity was measured as suppression of the respiratory burst stimulated by phorbol myristate acetate subsequent to exposure (43.5% depression by 2-h exposure to 5 atm absolute O2 vs. controls). The presence of extracellular glutathione significantly protected these cells (7% loss). gamma-Glutamyl transpeptidase, a membrane enzyme with its active site directed outward, was necessary for use of extracellular glutathione. This was demonstrated using the
gamma-glutamyl transpeptidase
inhibitor, serine-borate complex, which significantly blocked both protection of cells by extracellular glutathione and extracellular glutathione-dependent synthesis of glutathione. The principal use of glutathione in antioxidant defense is as a substrate for glutathione peroxidase. The apparent Km for glutathione of glutathione peroxidase of rat alveolar macrophages was determined to be 2 mM; however, rat alveolar macrophages have approximately 1.3 mM intracellular glutathione, which is insufficient for maximal enzymatic activity. During hyperoxic exposure, this deficit would probably be more significant. Thus the ability of extracellular glutathione along with
gamma-glutamyl transpeptidase
activity to provide amino acids for de novo glutathione synthesis appears to be a potentially important component of antioxidant defense.
...
PMID:Protection of alveolar macrophages from hyperoxia by gamma-glutamyl transpeptidase. 197 90
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
Glutathione (GSH) administered intraperitoneally significantly prolongs the time to initial seizure and survival time of rats exposed to hyperbaric
hyperoxia
(HBO). Acivicin is an antitumor antibiotic that is an inhibitor of
gamma-glutamyl transpeptidase
(
GGT
), an enzyme necessary for the breakdown and transport across cell membranes of GSH. To determine whether acivicin treatment alters GSH-induced protection from HBO, rats were dosed with 25 mg/kg of acivicin or vehicle 1 h before O2 exposure at an inspired O2 fraction of 1.0 at 4 ATA. Immediately before exposure, rats received GSH (1 mmol/kg) or vehicle. Time to seizure and time to death were recorded during exposure by direct observation. In separate groups of rats on the same dosing schedule, plasma GSH, renal
GGT
, and brain
GGT
were measured 15 min after the GSH injection without HBO exposure and 100 min after the beginning of HBO exposure. Renal
GGT
was decreased to 2.5% of control and brain
GGT
to 37% of control in the acivicin-dosed rats. Plasma GSH increased 3-fold in rats given acivicin alone, 52-fold in rats given GSH alone, and 84-fold in rats receiving both acivicin and GSH. Rats dosed with GSH alone had significantly prolonged times to seizure and death compared with all other groups. Rats dosed with GSH after receiving acivicin were not protected from HBO despite the large increase in plasma GSH that occurred in these animals. GSH treatment did not increase tissue GSH in lung, liver, or brain at 160 or 200 min of exposure.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Elimination of glutathione-induced protection from hyperbaric hyperoxia by acivicin. 791 99
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.
...
PMID:Hyperoxia enhances expression of gamma-glutamyl transpeptidase and increases protein S-glutathiolation in rat lung. 877 34
Although the effect of
hyperoxia
on antioxidant enzymes is well known, the effect of subtoxic levels of
hyperoxia
on
gamma-glutamyltransferase
(
gamma-GT
), involved in the degradation and uptake of extracellular GSH for intracellular GSH synthesis, is unknown. The aim of the study was to investigate (1) the effects of in vitro
hyperoxia
on
gamma-GT
activity of type II cells and (2) the effects of the lazaroid U-74389G and N-acetylcysteine (NAC) on the
hyperoxia
-induced changes in
gamma-GT
and antioxidant enzyme activities. At 48 h after isolation, rat type II cells were exposed for 2 days to air, 60% O2 or 85% O2 with or without 30 microM U-74389G or 100 microM NAC. After the exposure, the cells were harvested and assayed for superoxide dismutase (SOD), glutathione peroxidase (GPx),
gamma-GT
activity, and GSH levels. In another series of experiments 85% O2-exposed cells, with or without U-74389G, were used for Northern blotting of
gamma-GT
mRNA. Exposure to 60% O2 decreased
gamma-GT
and GSH by -47 and -34%, respectively, while SOD and GPx activities remained unchanged. After 85% O2-exposure
gamma-GT
decreased by -55%, SOD and GPx increased by +55 and +87%, respectively, while GSH decreased by -35%. NAC treatment decreased
gamma-GT
activity by -42% in the air-exposed cells. After 60% O2, U-74389G led to significantly higher
gamma-GT
(+117%) and GSH (+26%) while NAC only led to higher GSH (+28%) compared to the oxygen-exposed cells not treated with NAC or U-74389G. After 85% O2 U-74389G increased
gamma-GT
, SOD, and GSH by +72, +58, and +68%, respectively, while NAC only increased SOD (+49%) and GSH (+26%) compared to the oxygen-exposed cells not treated with NAC or U-74389G. The 85% O2 exposure, with or without U-74389G, had no effect on
gamma-GT
mRNA levels. The results show that
hyperoxia
decreases rat type II cell
gamma-GT
activity in vitro. This effect was not related to an altered regulation at mRNA level and it was not associated with the
hyperoxia
-induced decrease in intracellular GSH, since restoration of the GSH levels by NAC did not restore
gamma-GT
activity. The lazaroid U-74389G with vitamin E-like properties effectively prevented the decrease in
gamma-GT
and GSH, so that direct inactivation of the membrane-bound
gamma-GT
by
hyperoxia
is the most likely mechanism.
...
PMID:Decrease in gamma-glutamyltransferase activity in rat type II cells exposed in vitro to hyperoxia: effects of the 21-aminosteroid U-74389G. 920 59
The effect of
hyperoxia
on
gamma-glutamyltransferase
(
gamma-GT
), an important enzyme for the uptake of precursor molecules for intracellular synthesis of glutathione (GSH), has not been established. Our aim was to investigate the effects of prolonged subtoxic levels of
hyperoxia
on
gamma-GT
activity and GSH levels in lung tissue, epithelial lining fluid (ELF), and isolated rat type II cells immediately after their isolation and 48 h later when kept in culture in normoxia. Seventeen male Wistar rats were divided in three groups (n = 5-7) and were exposed to air or to 60 or 85% O2 for 7 days. Pulmonary
gamma-GT
activity increased in the 60 and 85% O2-exposed animals (1.6- and 3.2-fold, respectively), and tissue GSH levels increased only in the 60% O2 group (1.3-fold). In isolated type II cells from 60 and 85% O2-exposed animals,
gamma-GT
activity decreased by -70 and -88%, respectively, which was supported by cytochemical staining. Type II cell
gamma-GT
mRNA expression tended only to decrease after 85% O2. Type II cell
gamma-GT
activity strongly correlated with ELF
gamma-GT
(r = 0.60, P < 0.001), and ELF
gamma-GT
strongly correlated with ELF GSH (r = 0.75, P < 0.0001). When in culture, type II cell
gamma-GT
activity and GSH levels remained, respectively, 2.5- and 1.9-fold lower in the 60% O2-exposed group, but, in the 85% O2-exposed group,
gamma-GT
activity increased 2.1-fold, and GSH levels dropped to the levels of the control cells.
Hyperoxia
led to a concentration-dependent decrease in
gamma-GT
activity in rat type II cells, possibly by direct inactivation, but led to an increase in whole lung tissue
gamma-GT
. There seemed to be a negative feedback between intracellular GSH levels and type II cell
gamma-GT
activity.
gamma-GT
levels in the ELF were correlated with type II cell
gamma-GT
activity, but ELF
gamma-GT
did not seem to play an active role in the regulation of the ELF GSH pool.
Hyperoxia
decreased ELF GSH levels, possibly by increased degradation of GSH in the parenchymal lung tissue as a result of the increased
gamma-GT
activity.
...
PMID:Changes in gamma-glutamyltransferase activity in rat lung tissue, BAL, and type II cells after hyperoxia. 931 87
Although the antioxidant properties of N-acetylcysteine (NAC) in vitro are widely accepted, the efficacy of NAC in the prevention of O2 toxicity in vivo is poorly documented. The aim of our study was to investigate the presumed protective effect of NAC on hyperoxic lung injury, focusing on
gamma-glutamyltransferase
(
gamma-GT
) activity and glutathione (GSH) levels in lung tissue, epithelial lining fluid (ELF), and isolated rat type II cells immediately after their isolation and 48 h later when kept in culture in normoxia. Thirty-four male Wistar rats were divided in three groups (n = 10-14) and were exposed to air or to 60 or 85% O2 for 7 days. One-half of the rats in each group received 200 mg/kg NAC intraperitoneally one time per day from 3 days before exposure until the end of the experiment, and the other one-half received the vehicle. In the 85% O2-exposed animals, NAC led to more respiratory distress and weight loss. NAC did not prevent the rise in bronchoalveolar lavage lactate dehydrogenase and alkaline phosphatase, but it did prevent the rise in calculated ELF volume. NAC decreased GSH levels (1.4-fold) and
gamma-GT
activity (1.8-fold) in the air-exposed type II cells. In the 60% O2-exposed group, no effects of NAC were seen (except for a decrease in
gamma-GT
mRNA expression), but, in the 85% O2-exposed group, NAC gave rise to higher GSH (2.6-fold) and higher
gamma-GT
activity (2.9-fold) in the ELF and lower GSH (6.9-fold) and higher
gamma-GT
activity (3.6-fold) in the type II cells. Even in culture, GSH levels remained 1.5-fold lower than in the cells from the air-exposed animals and 2-fold lower than in the cells from the 85% O2-exposed animals. There was increased DNA damage (as assessed by thymidine incorporation) and apoptosis after
hyperoxia
, especially after 60% O2, and this effect was amplified after NAC treatment. Although protective at the endothelial side, NAC treatment led to adverse effects at the epithelial side, despite, or probably because of, restoration of the ELF GSH levels in the presence of high O2 levels. Because NAC is rapidly metabolized to cysteine, it is plausible that the effects of NAC are manifested through the toxic effects of cysteine.
...
PMID:N-acetylcysteine does not protect against type II cell injury after prolonged exposure to hyperoxia in rats. 931 88
We studied the regulation of GSH and the enzymes involved in GSH regulation, gamma-glutamylcysteine synthetase (gamma-GCS) and
gamma-glutamyl transpeptidase
(
gamma-GT
), in response to the oxidants menadione, xanthine/xanthine oxidase,
hyperoxia
, and cigarette smoke condensate in human alveolar epithelial cells (A549). Menadione (100 microM), xanthine/xanthine oxidase (50 microM/10 mU), and cigarette smoke condensate (10%) exposure produced increased GSH levels (240 +/- 6, 202 +/- 12, and 191 +/- 2 nmol/mg protein, respectively; P < 0.001) compared with the control level (132 +/- 8 nmol/mg protein), which were associated with a significant increase in gamma-GCS activity (0.18 +/- 0.006, 0.16 +/- 0.01, and 0.17 +/- 0. 008 U/mg protein, respectively; P < 0.01) compared with the control level (0.08 +/- 0.001 U/mg protein) at 24 h. Exposure to
hyperoxia
(95% O2) resulted in a time-dependent increase in GSH levels. gamma-GCS activity increased significantly at 4 h (P < 0.001), returning to control values after 12 h of exposure. Dexamethasone (3 microM) exposure produced a significant time-dependent decrease in the levels of GSH and gamma-GCS activity at 24-96 h. The activity of
gamma-GT
did not change after oxidant treatment; however, it was decreased significantly by dexamethasone at 24-96 h. Thus oxidants and dexamethasone modulate GSH levels and activities of
gamma-GT
and gamma-GCS by different mechanisms. We suggest that the increase in gamma-GCS activity but not in
gamma-GT
activity may be required for the increase in intracellular GSH under oxidative stress in alveolar epithelial cells.
...
PMID:Differential regulation of glutathione by oxidants and dexamethasone in alveolar epithelial cells. 968 38
Depletion of glutathione, a key antioxidant, accelerates lung injury. Glutathione concentrations are reduced significantly in premature infants with respiratory distress syndrome, leaving them at greater risk of bronchopulmonary dysplasia. A study was designed to verify if the increased glutathione synthetic activity observed in oxygen-dependent and ventilated newborn infants was caused by their postsurgical state. Our objective was to evaluate the role of a general surgical procedure as a factor affecting lung glutathione. One-day-old guinea pig pups, a well characterized animal model for the study of neonatal lung disease, were divided between those undergoing a standardized surgical procedure and those that did not. The pups were fed by their mother. After 4 days the lungs were sampled to determine total glutathione content, activities of
gamma-glutamyltranspeptidase
, glutathione peroxidase, and reductase as well as the glutathione synthetic activity. The surgical procedure was associated with a specific stimulatory effect limited to glutathione synthetic activity (p < 0.02) leading to an increased (p < 0.02) pulmonary glutathione content. Glutathione concentration was significantly correlated (r2 = 0.67) with the synthetic activity. We concluded that in this animal model an invasive procedure such as a general surgical procedure affects lung glutathione metabolism in a fashion similar to that of
hyperoxia
. In the lungs, the synthetic activity is a stronger determinant of glutathione concentrations than the activities of the other enzymes involved in maintaining glutathione levels.
...
PMID:Glutathione synthetic activity in the lungs in newborn guinea pigs. 983 29
Influence of oxygen on lung cell differentiation has been studied in precision-cut rat lung slice cultures. Rat lung slices were positioned on rolling inserts placed into vials with opened caps to allow free access to the gaseous phase. This system was placed into a continuous-flow rotating chamber with controlled pO(2), pCO(2) and hygrometry. Slices were cultured in a serum-free medium up to 3 days under an atmosphere of 21 or 70% oxygen. Cellular antioxidant markers demonstrated an oxygen concentration-dependent response. Slices cultured with 70% oxygen exhibited the highest specific activity of catalase, NADPH cytochrome c reductase and
gamma-glutamyl transpeptidase
(
GGT
) as well as the highest levels of intracellular glutathione after 48 or 72 hours of incubation. Moreover, hyperoxic exposure altered the expression of lung manganese-containing superoxide dismutase mRNA.
Hyperoxia
had little or no effect on intracellular ATP levels, which remained high in lung slices compared with freshly isolated tissue. The study of the pulmonary specific functions allowed to confirm maintenance of the in vitro cellular differentiation of lung slices incubated with 21% oxygen: (i) polyamine transport is preserved and exhibited kinetic properties similar to those observed in lung in vivo; (ii) ATP levels remained constant throughout the time course of incubation. This in vitro model proves to be a useful tool to study mechanisms involved after oxygen exposure and will probably be useful for the study of other environmental gaseous contaminants. Further developments in this method are under development.
...
PMID:Characterization of Precision-cut Rat Lung Slices in a Biphasic Gas/Liquid Exposure System: Effect of O(2). 2065 4
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