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Query: UMLS:C0242706 (
hyperoxia
)
5,219
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Exposure of the lung to severe
hyperoxia
induces terminal transferase dUTP end-labeling (TUNEL) indicative of DNA damage or apoptosis and increases expression of the tumor suppressor p53 and of members of the Bcl-2 gene family. Because cell survival and apoptosis are regulated, in part, by the relative abundance of proteins of the Bcl-2 family, we hypothesized that lung cells dying during exposure would show increased expression of pro-apoptotic members, such as Bax, whereas surviving cells would have increased expression of anti-apoptotic members, such as
Bcl-X
(L). The hypothesis is tested in the current study by determining which Bcl-2 genes are regulated by
hyperoxia
, with specific focus on correlating expression of Bax and
Bcl-X
(L) with morphologic evidence of apoptosis or necrosis. Adult mice exposed to greater than 95% oxygen concentrations for 48 to 88 hours had increased whole-lung mRNA levels of Bax and
Bcl-X
(L), no change in Bak, Bad, or Bcl-2, and decreased levels of Bcl-w and Bfl-1. In situ hybridization revealed that
hyperoxia
induced Bax and
Bcl-X
(L) mRNA in uniform and overlapping patterns of expression throughout terminal bronchioles and parenchyma, coinciding with TUNEL staining. Electron microscopy and DNA electrophoresis, however, suggested relatively little classical apoptosis. Unexpectedly, Western analysis demonstrated increased
Bcl-X
(L), but not Bax, protein in response to
hyperoxia
. Bax and Bfl-1 were not altered by
hyperoxia
in p53 null mice; however, oxygen toxicity was not lessened by p53 deficiency. These findings suggest that oxygen-induced lung injury does not depend on the relative expression of these Bcl-2 members.
...
PMID:Bcl-2 family gene expression during severe hyperoxia induced lung injury. 1114 Jun 97
Exposure of animals to
hyperoxia
results in lung injury that is characterized by apoptosis and necrosis of the alveolar epithelium and endothelium. The mechanism by which
hyperoxia
results in cell death, however, remains unclear. We sought to test the hypothesis that exposure to
hyperoxia
causes mitochondria-dependent apoptosis that requires the generation of reactive oxygen species from mitochondrial electron transport. Rat1a cells exposed to
hyperoxia
underwent apoptosis characterized by the release of cytochrome c, activation of caspase-9, and nuclear fragmentation that was prevented by the overexpression of
Bcl-X
(L.) Murine embryonic fibroblasts from bax(-/-) bak(-/-) mice were resistant to
hyperoxia
-induced cell death. The administration of the antioxidants manganese (III) tetrakis (4-benzoic acid) porphyrin, ebselen, and N-acetylcysteine failed to prevent cell death following exposure to
hyperoxia
. Human fibrosarcoma cells (HT1080) lacking mitochondrial DNA (rho(0) cells) that failed to generate reactive oxygen species during exposure to
hyperoxia
were not protected against cell death following exposure to
hyperoxia
. We conclude that exposure to
hyperoxia
results in apoptosis that requires Bax or Bak and can be prevented by the overexpression of
Bcl-X
(L). The mitochondrial generation of reactive oxygen species is not required for cell death following exposure to
hyperoxia
.
...
PMID:Hyperoxia-induced apoptosis does not require mitochondrial reactive oxygen species and is regulated by Bcl-2 proteins. 1187 88
Hypoxic brain injury during fetal or neonatal development leads to damaged immature neurons and can result in cognitive or behavioral dysfunction.
Hyperoxia
therapy (treatment with oxygen) is commonly applied to infants with signs of perinatal hypoxia-anoxia. Both hypoxia and
hyperoxia
have been shown to result in apoptosis in the brains of rats in several animal models. One determinant of cellular commitment to cell death is the differential expression of the Bcl-2 family of proteins in response to trauma. Here, we characterize cell death and the expression of Bcl-2 homologous proteins in 7-day-old neonatal rat cerebral cortex after hypoxia (5% O(2) for 40 min) and/or
hyperoxia
(>95% O(2) for 2 h after hypoxia). The expression of Bcl-2 and
Bcl-X
(L), two anti-apoptotic proteins, decreased at 24 h after hypoxia.
Bcl-X
(L) increased after either
hyperoxia
or hypoxia+hyperoxia. We did not detect significant changes in the cytoplasmic levels of pro-apoptotic protein Bax after any of these three treatments. Using cell death ELISA and DNA FragEL assays, we observed increased cell death at 24h after hypoxia,
hyperoxia
or hypoxia+hyperoxia treatments. At 24 h after either hypoxia,
hyperoxia
or hypoxia+hyperoxia, caspase 3 activity also increased significantly. Our results suggest that both hypoxia and
hyperoxia
alone can induce cell death. The Bcl-2 --> cytochrome c --> caspase 3 pathway played a role in hypoxia-induced cell death, while other pathways may be involved in
hyperoxia
-induced cell death.
...
PMID:Bcl-2 family members make different contributions to cell death in hypoxia and/or hyperoxia in rat cerebral cortex. 1459 83
p21(Cip1/WAF1/Sdi1) is a major transcriptional target of p53 that promotes survival of cells exposed to continuous oxidative stress caused by
hyperoxia
. Because p21 can protect against genotoxic stress by reducing p53-dependent transcription of the proapoptotic proteins PUMA and Bax, the current study uses genetically modified lines of HCT116 colon carcinoma cells to investigate whether p21-mediated protection against
hyperoxia
involves attenuation of the p53 apoptotic pathway.
Hyperoxia
stimulated p53-dependent expression of p21 and Bax. Genetic ablation of p21 increased cell death, and loss of Bax or PUMA increased cell survival. Unlike damage caused by adriamycin, whereby p21 sensitivity could be rescued by removal of p53, PUMA, or Bax, increased sensitivity of p21-deficient cells to
hyperoxia
could not be rescued by additional loss of these genes. Instead, expression of the antiapoptotic protein
Bcl-X
(L) declined in p21-deficient cells exposed to
hyperoxia
, but when genetically restored, increased their survival. Conversely, siRNA knockdown of
Bcl-X
(L) in parental HCT116 cells increased
hyperoxia
-induced cell death. These findings reveal that p21-mediated protection against
hyperoxia
does not involve attenuation of p53-dependent apoptosis, but rather functions to maintain
Bcl-X
(L) expression during periods of persistent oxidative stress.
...
PMID:p21(Cip1/Waf1/Sdi1) protects against hyperoxia by maintaining expression of Bcl-X(L). 1686 93
Hyperoxia
causes cell injury and death associated with reactive oxygen species formation and inflammatory responses. Recent studies show that
hyperoxia
-induced cell death involves apoptosis, necrosis, or mixed phenotypes depending on cell type, although the underlying mechanisms remain unclear. Using murine lung endothelial cells, we found that
hyperoxia
caused cell death by apoptosis involving both extrinsic (Fas-dependent) and intrinsic (mitochondria-dependent) pathways.
Hyperoxia
-dependent activation of the extrinsic apoptosis pathway and formation of the death-inducing signaling complex required NADPH oxidase-dependent reactive oxygen species production, because this process was attenuated by chemical inhibition, as well as by genetic deletion of the p47(phox) subunit, of the oxidase. Overexpression of heme oxygenase-1 prevented
hyperoxia
-induced cell death and cytochrome c release. Likewise, carbon monoxide, at low concentrations, markedly inhibited
hyperoxia
-induced endothelial cell death by inhibiting cytochrome c release and caspase-9/3 activation. Carbon monoxide, by attenuating
hyperoxia
-induced reactive oxygen species production, inhibited extrinsic apoptosis signaling initiated by death-inducing signal complex trafficking from the Golgi apparatus to the plasma membrane and downstream activation of caspase-8. We also found that carbon monoxide inhibited the
hyperoxia
-induced activation of Bcl-2-related proteins involved in both intrinsic and extrinsic apoptotic signaling. Carbon monoxide inhibited the activation of Bid and the expression and mitochondrial translocation of Bax, whereas promoted
Bcl-X
(L)/Bax interaction and increased Bad phosphorylation. We also show that carbon monoxide promoted an interaction of heme oxygenase-1 with Bax. These results define novel mechanisms underlying the antiapoptotic effects of carbon monoxide during hyperoxic stress.
...
PMID:Carbon monoxide protects against hyperoxia-induced endothelial cell apoptosis by inhibiting reactive oxygen species formation. 1713 72
The tumor suppressor protein p53 activates growth arrest and proapoptotic genes in response to DNA damage. It is known that negative feedback by p21(Cip1/Waf1/Sdi1) represses p53-dependent transactivation of PUMA. The current study investigates PUMA feedback on p53 during oxidative stress from
hyperoxia
and the subsequent effects on cell survival mediated through p21 and
Bcl-X
(L). Deletion of PUMA in HCT116 colon carcinoma cells increased levels of p53 and p21, resulting in a larger G(1) population during
hyperoxia
. P21-dependent increase in
Bcl-X
(L) levels protected PUMA-deficient cells against hyperoxic cell death. Bax and Bak were both able to promote hyperoxic cell death.
Bcl-X
(L) protection against hyperoxic death was lost in cells lacking Bax, not PUMA, suggesting that
Bcl-X
(L) acts to inhibit Bax-dependent death. These results indicate that PUMA exerts a negative feedback on p53 and p21, leading to p21-dependent growth suppressive and survival changes. Enhanced survival was associated with increased
Bcl-X
(L) to block Bax activated cell death during oxidative stress.
...
PMID:PUMA inactivation protects against oxidative stress through p21/Bcl-XL inhibition of bax death. 1821 42
Although it is well established that the cell cycle inhibitor p21 protects against genotoxic stress by preventing the replication of damaged DNA, recent studies have shown that the cytoplasmic form can also protect. It protects by delaying the loss of the antiapoptotic proteins Mcl-1 and
Bcl-X
(L); however, the mechanism of regulation is unknown. Utilizing
hyperoxia
as a model of chronic oxidative stress and DNA damage, p21 was detected in the nucleus and cytoplasm and cytoplasmic expression of p21 was sufficient for cytoprotection. p21 was enriched in a subcellular fraction containing mitochondria and endoplasmic reticulum (ER), suggesting that it may be coordinating ER and mitochondrial stress pathways. Consistent with this, p21 suppressed hyperoxic downregulation of BiP and subsequent activation of ER stress signaling, which affected Mcl-1, but not
Bcl-X
(L); though both inhibited hyperoxic cell death. Taken together, these data show that p21 integrates the DNA damage response with ER stress signaling, which then regulates mitochondrial death pathways during chronic genotoxic stress.
...
PMID:p21(Cip1) protects against oxidative stress by suppressing ER-dependent activation of mitochondrial death pathways. 1894 88
Recent studies indicate that the antiapoptotic
Bcl-X
(L), one of five isoforms expressed by the
Bcl-X
gene, protects a variety of cell lines exposed to
hyperoxia
. However, its role in lung development and protection against oxidative stress in vivo is not known. Here, we show
Bcl-X
(L) is the predominant isoform expressed in the lung, and the only isoform detected in respiratory epithelium. Because loss of
Bcl-X
(L) is embryonically lethal,
Bcl-X
(L) was ablated throughout the respiratory epithelium by mating mice with a floxed exon II of the
Bcl-X
gene with mice expressing Cre under control of the surfactant protein-C promoter. Interestingly, the loss of
Bcl-X
(L) in respiratory epithelium was perinatally lethal in approximately 50% of the expected offspring. However, some adult mice lacking the gene were obtained. The epithelial-specific ablation of
Bcl-X
(L) did not disrupt pulmonary function, the expression of epithelial cell-specific markers, or lung development. However, it shifted the lung toward a proapoptotic state, defined by a reduction in antiapoptotic Mcl-1, an increase in proapoptotic Bak, and increased sensitivity of the respiratory epithelium to
hyperoxia
. Intriguingly, increased 8-oxoguanine lesions seen during
hyperoxia
were also evident as lungs transitioned to room air at birth, a time when perinatal lethality in some mice lacking
Bcl-X
(L) was observed. These findings reveal that the epithelial-specific expression of
Bcl-X
(L) is not required for proper lung development, but functions to protect respiratory epithelial cells against oxygen-induced toxicity, such as during
hyperoxia
and the lung's first exposure to ambient air.
...
PMID:Epithelial ablation of Bcl-XL increases sensitivity to oxygen without disrupting lung development. 1988 Aug 21
A tight balance between anti- and proapoptotic members of the Bcl-2 family controls cell survival and death. Exposure to
hyperoxia
shifts this balance towards a prodeath state that ultimately activates Bak- and Bax-dependent cell death. Mechanisms underlying this shift are undefined; however, the cell cycle inhibitor p21 delays the loss of antiapoptotic Mcl-1 and
Bcl-X
(L), and protects against
hyperoxia
. Here, H1299 human lung adenocarcinoma cells are used to investigate how these and other members of the Bcl-2 family cooperate with p21 to protect against
hyperoxia
. Expression of antiapoptotic Mcl-1 and
Bcl-X
(L), but not Bcl-2 or A1, declined during
hyperoxia
, whereas proapoptotic Bak, but not Bax, increased. Conditional overexpression of p21 selectively delayed the loss of Mcl-1 and
Bcl-X
(L), without affecting expression of the other members. siRNA knockdown of Mcl-1 and
Bcl-X
(L) sensitized cells to
hyperoxia
, but only the loss of
Bcl-X
(L) ablated the protective effects of p21. Conversely, overexpression of Mcl-1 and
Bcl-X
(L) protected against
hyperoxia
, but only
Bcl-X
(L) bound Bak and Bax. Altogether, these data suggest that
Bcl-X
(L) is the primary mediator by which p21 protects against
hyperoxia
-induced Bak/Bax-dependent cell death.
...
PMID:Bcl-X(L) is the primary mediator of p21 protection against hyperoxia-induced cell death. 2112 58
Rats reared in
hyperoxia
have smaller carotid bodies as adults. To study the time course and mechanisms underlying these changes, rats were reared in 60% O(2) from birth and their carotid bodies were harvested at various postnatal ages (P0-P7, P14). The carotid bodies of
hyperoxia
-reared rats were smaller than those of age-matched controls beginning at P4. In contrast, 7d of 60% O(2) had no effect on carotid body size in rats exposed to
hyperoxia
as adults. Bromodeoxyuridine (BrdU) and TdT-mediated dUTP nick end labeling (TUNEL) were used to assess cell proliferation and DNA fragmentation at P2, P4, and P6.
Hyperoxia
reduced the proportion of glomus cells undergoing cell division at P4; although a similar trend was evident at P2,
hyperoxia
no longer affected cell proliferation by P6. The proportion of TUNEL-positive glomus cells was modestly increased by
hyperoxia
. We did not detect changes in mRNA expression for proapoptotic (Bax) or antiapoptotic (
Bcl-X
(L)) genes or transcription factors that regulate cell cycle checkpoints (p53 or p21), although mRNA levels for cyclin B1 and cyclin B2 were reduced. Collectively, these data indicate that
hyperoxia
primarily attenuates postnatal growth of the carotid body by inhibiting glomus cell proliferation during the first few days of exposure.
...
PMID:Carotid body growth during chronic postnatal hyperoxia. 2213 79
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