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)

Destruction of pulmonary endothelial cells is characteristic of hyperoxic lung injury. During recovery from hyperoxia, pulmonary endothelial cells proliferate to regenerate the vascular endothelium. Vascular endothelial growth factor (VEGF) is a peptide growth factor that is mitogenic specifically for endothelial cells. We hypothesized that VEGF messenger RNA (mRNA) increases during recovery from acute hyperoxic lung injury. Adult rabbits were exposed to 100% oxygen for 64 h and allowed to recover in air for 0, 1, 3, and 5 days. In situ hybridization showed increased VEGF expression in alveolar epithelial cells beginning at 1 day recovery. By 3 days recovery the message was in alveolar epithelial cells throughout the lung. Compared with alveolar epithelial cells, little or no expression was noted in large vessel endothelial cells, airway cells, or smooth muscle cells. Combined in situ hybridization for VEGF and immunostaining for macrophages and other mesenchymal cells found no VEGF message in those cell types. Isolated alveolar macrophages had no detectable VEGF message. Cells expressing VEGF mRNA were enriched in alveolar type II cell preparations from recovering lung. Double in situ hybridization for VEGF and surfactant protein-C (SP-C) showed co-expression in a population of type II cells, but with an inverse relationship: cells with abundant VEGF mRNA did not have abundant SP-C mRNA. Type II cells in vitro expressed VEGF message, but only when the SP-C message abundance was relatively low. We conclude that alveolar type II cells express increased VEGF mRNA during recovery from acute hyperoxia. These findings are consistent with a role for VEGF in regulating microvascular endothelial repair after oxidant injury.
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PMID:Vascular endothelial growth factor mRNA increases in alveolar epithelial cells during recovery from oxygen injury. 754 67

Cell-to-cell communication is often disrupted when tissue damage occurs, triggering new signals to cope with the injury. The expression of intercellular adhesion molecule (ICAM-1), a protein involved in the migration, binding, and activation of leukocytes, is markedly increased in mouse lungs damaged by acute hyperoxic exposure. Type I alveolar epithelial cells are sensitive to hyperoxic lung injury, and must be removed from the air spaces following their destruction. In contrast, type II pneumocytes are relatively resistant to hyperoxia and may have a role in the removal process. Two reports demonstrate increased ICAM-1 in alveoli after hyperoxia (Welty et al., 1993, AJRCMB 9:393-400; and Kang et al., 1993, AJRCMB 9:350-355), but the cellular site(s) of ICAM-1 synthesis were not determined. We hypothesized that during in vivo exposure to 100% oxygen (O2), type II pneumocytes synthesize and secrete ICAM-1, an important step in attracting inflammatory cells to the site of injury. Adult mice were exposed to 100% O2 for up to 72 h. To determine whether type II cells express ICAM-1, tissue sections were studied by electron microscopy single-label in situ hybridization or light microscopy dual-label in situ hybridization, using radiolabeled and nonradiolabeled probes. In the lungs of unexposed animals, ICAM-1 mRNA was detected in many cells-including type I pneumocytes-but not in type II cells. After hyperoxia, ICAM-1 transcripts were detected in bona fide, surfactant protein C mRNA-containing, type II alveolar epithelial cells. This observation suggests that type II cells play an important and previously unrecognized role in pulmonary inflammation from O2 toxicity and emphasizes the importance of type II pneumocytes in alveolar repair after injury.
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PMID:In vivo expression of intercellular adhesion molecule 1 in type II pneumocytes during hyperoxia. 867 24

Clara cell secretory protein (CCSP) deficiency in mice is associated with increased susceptibility to pulmonary inflammation after hyperoxia or viral infection. Because adenoviral exposure perturbs pulmonary surfactant homeostasis in vivo, we hypothesized that CCSP deficiency would influence surfactant metabolism after pulmonary infection. Alveolar and total lung saturated phosphatidylcholine pool sizes were similar in CCSP-deficient [CCSP(-/-)] and wild-type [CCSP(+/+)] mice before and 7 days after intratracheal administration of adenovirus. Radiolabeled choline and palmitate incorporation into saturated phosphatidylcholine was similar, and there was no alteration by previous infection 7 days before the incorporation measurements. Furthermore, CCSP deficiency did not influence clearance of [(14)C]dipalmitoylphosphatidylcholine and (125)I-labeled recombinant surfactant protein C. Increased persistence of alveolar capillary leak was observed in CCSP(-/-) mice after adenoviral infection. Surfactant lipid homeostasis was not influenced by CCSP before or after administration of adenovirus to the lung. Persistence of alveolar capillary leak in CCSP(-/-) mice after adenovirus provides further evidence for the role of CCSP in the regulation of pulmonary inflammation.
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PMID:CCSP deficiency does not alter surfactant homeostasis during adenoviral infection. 1056 84

We have previously shown that cyclosporin A (CsA), an inhibitor of protein phosphatase 2B (calcineurin), attenuates hyperoxia-induced reductions in murine lung compliance. CsA protected against hyperoxia-induced changes in neutrophil infiltration, capillary congestion, edema, and hyaline membrane formation. Gene expression studies were conducted to identify the gene expression patterns underlying the protective effects of CsA during hyperoxic lung injury. After 72 h of simultaneous treatment with >95% oxygen and CsA (50 mg x kg(-1) x day(-1)), RNA was isolated from murine lungs. RNA from treated and untreated lungs was reverse transcribed to cDNA, competitively hybridized, and used to probe 8,734 complimentary DNAs on the Incyte mouse GEM 1 array. Several known genes and expressed sequence tags (ESTs) showed increased (GenBank accession numbers: AA125385, AA241295, W87197, syntaxin, and cyclin G) or decreased [AA036517, AA267567, AA217009, W82577, uteroglobin, stromal cell-derived factor 1, and surfactant protein C (SP-C)] expression after hyperoxia. Hyperoxia-stimulated reductions in SP-C gene expression were confirmed through Northern blot analysis. The increase in gene expression of one expressed sequence tag (AA125385) with hyperoxia was reversed by CsA treatment. Sequence data demonstrated that this EST has high homology to murine cyclin B1. Western blot analysis did not demonstrate any changes in distal lung cyclin B1 expression after hyperoxia. Protein expression of cyclin B1 in the distal lung was observed in the endothelial cells, bronchiolar epithelial cells, and both the type I and type II alveolar epithelial cells. Further analysis of cyclin B1 may elucidate the protective actions of CsA in hyperoxic injury.
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PMID:Protection of lungs from hyperoxic injury: gene expression analysis of cyclosporin A therapy. 1277 87

Acute lung injury syndromes remain common causes of morbidity and mortality in adults and children. Cellular and physiologic mechanisms maintaining pulmonary homeostasis during lung injury remain poorly understood. In the present study, the Stat-3 gene was selectively deleted in respiratory epithelial cells by conditional expression of Cre-recombinase under control of the surfactant protein C gene promoter. Cell-selective deletion of Stat-3 in respiratory epithelial cells did not alter prenatal lung morphogenesis or postnatal lung function. However, exposure of adult Stat-3-deleted mice to 95% oxygen caused a more rapidly progressive lung injury associated with alveolar capillary leak and acute respiratory distress. Epithelial cell injury and inflammatory responses were increased in the Stat-3-deleted mice. Surfactant proteins and lipids were decreased or absent in alveolar lavage material. Intratracheal treatment with exogenous surfactant protein B improved survival and lung histology in Stat-3-deleted mice during hyperoxia. Expression of Stat-3 in respiratory epithelial cells is not required for lung formation, but plays a critical role in maintenance of surfactant homeostasis and lung function during oxygen injury.
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PMID:Stat-3 is required for pulmonary homeostasis during hyperoxia. 1470 6

It is well established that hyperoxia injures and kills alveolar endothelial and type I epithelial cells of the lung. Although type II epithelial cells remain morphologically intact, it remains unclear whether they are also damaged. DNA integrity was investigated in adult mice whose type II cells were identified by their endogenous expression of pro-surfactant protein C or transgenic expression of enhanced green fluorescent protein. In mice exposed to room air, punctate perinuclear 8-oxoguanine staining was detected in approximately 4% of all alveolar cells and in 30% of type II cells. After 48 or 72 h of hyperoxia, 8-oxoguanine was detected in 11% of all alveolar cells and in >60% of type II cells. 8-Oxoguanine colocalized by confocal microscopy with the mitochondrial transmembrane protein cytochrome oxidase subunit 1. Type II cells isolated from hyperoxic lungs exhibited nuclear DNA strand breaks by comet assay even though they were viable and morphologically indistinguishable from cells isolated from lungs exposed to room air. These data reveal that type II cells exposed to in vivo hyperoxia have oxidized and fragmented DNA. Because type II cells are essential for lung remodeling, our findings raise the possibility that they are proficient in DNA repair.
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PMID:In vivo exposure to hyperoxia induces DNA damage in a population of alveolar type II epithelial cells. 1472 12

It is well established that exposure to high levels of oxygen (hyperoxia) injures and kills microvascular endothelial and alveolar type I epithelial cells. In contrast, significant death of airway and type II epithelial cells is not observed at mortality, suggesting that these cell types may express genes that protect against oxidative stress and damage. During a search for genes induced by hyperoxia, we previously reported that airway and alveolar type II epithelial cells uniquely express the growth arrest and DNA damage (Gadd)45a gene. Because Gadd45a has been implicated in protection against genotoxic stress, adult Gadd45a (+/+) and Gadd45a (-/-) mice were exposed to hyperoxia to investigate whether it protected epithelial cells against oxidative stress. During hyperoxia, Gadd45a deficiency did not affect loss of airway epithelial expression of Clara cell secretory protein or type II epithelial cell expression of pro-surfactant protein C. Likewise, Gadd45a deficiency did not alter recruitment of inflammatory cells, edema, or overall mortality. Consistent with Gadd45a not affecting the oxidative stress response, p21(Cip1/WAF1) and heme oxygenase-1 were comparably induced in Gadd45a (+/+) and Gadd45a (-/-) mice. Additionally, Gadd45a deficiency did not affect oxidative DNA damage or apoptosis as assessed by oxidized guanine and terminal deoxyneucleotidyl transferase-mediated dUTP nick-end labeling staining. Overexpression of Gadd45a in human lung adenocarcinoma cells did not affect viability or survival during exposure, whereas it was protective against UV-radiation. We conclude that increased tolerance of airway and type II epithelial cells to hyperoxia is not attributed solely to expression of Gadd45a.
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PMID:Loss of Gadd45a does not modify the pulmonary response to oxidative stress. 1565 12

Transgenic (TG) human (h) extracellular superoxide dismutase (EC-SOD) targeted to type II cells protects postnatal newborn mouse lung development against hyperoxia by unknown mechanisms. Because alveolar development depends on timely proliferation of type II epithelium and differentiation to type I epithelium, we measured proliferation in bronchiolar and alveolar (surfactant protein C-positive) epithelium in air and 95% O2-exposed wild-type (WT) and TG hEC-SOD newborn mice at postnatal days 3, 5, and 7 (P3-P7), traversing the transition from saccular to alveolar stages. We found that TG hEC-SOD ameliorated the 95% O2-impaired bromodeoxyuridine uptake in alveolar and bronchiolar epithelium at P3, but not at P5 and P7, when overall epithelial proliferation rates were lower in air-exposed WT mice. Mouse EC-, CuZn-, and Mn-SOD expression were unaffected by hyperoxia or genotype. TG mice had less DNA damage than 95% O2-exposed WT mice at P3, measured by TdT-mediated dUTP nick end labeling (P < 0.05). Hyperoxia induced cell-cycle inhibitory protein p21cip/waf mRNA at P3, WT > TG, P = 0.06. 95% O2 impaired apical expression of type I cell alpha protein (T1alpha) in WT but not in TG mice at P3 and increased T1alpha in WT and TG mice at P7. Reducing the 95% O2-induced impairment of epithelial proliferation at a critical window of lung development was associated with protection against DNA damage and preservation of apical T1alpha expression at P3.
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PMID:Transgenic extracellular superoxide dismutase protects postnatal alveolar epithelial proliferation and development during hyperoxia. 1610 Feb 89

To explore the mechanism of Notch in hyperoxia-induced preterm rat lung injury, 2-days-old preterm SD rats were randomized into control and hyperoxia group (FiO2 > or = 0.85). On day 1, 7, 14 and 21, 8 rat pups of each time point were used to assess histopathological changes of lung with HE staining and to evaluate the expression of Notch1 and Notch3 with immunohistochemistry. Notch1, Notch3, Aquaprin5 (AQP5) and surfactant protein C (SP-C) mRNA were measured by reverse transcription polymerase chain reaction (RT-PCR). The results showed that the lung injury in the hyperoxia group was characterized by retarded lung alveolization and differentiation of alveolar epithelial type II cells (AEC II). Positive staining of Notch1 in hyperoxia group was weaker than controls at every time point (except for day 7), while positive staining of Notch3 was much stronger (P < 0.05, P < 0.01). Notch1, Notch3 mRNA level showed similar change as protein level. AQP5, SP-C mRNA decreased significantly as compared with that of the controls (P < 0.01). We are led to conclude that hyperoxia results in abnormal expression of Notch, which is likely to contribute to the pathogenesis of lung injury through regulating proliferation and transdifferentiation of alveolar epithelial cells.
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PMID:Temporal expression of Notch in preterm rat lungs exposed to hyperoxia. 1611 61

In this study, C57BL/6J mice were exposed to hyperoxia and allowed to recover in room air. The sublethal dose of hyperoxia for C57BL/6J was 48 h. Distal lung cellular isolates from treated animals were characterized as 98% epithelial, with minor fibroblast and endothelial cell contaminants. Cells were then verified as 95% pure alveolar epithelial type II cells (AEC2) by surfactant protein C (SP-C) expression. After hyperoxia exposure in vivo, fresh, uncultured AEC2 were analyzed for proliferation by cell yield, cell cycle, PCNA expression, and telomerase activity. DNA damage was assessed by TdT-dUTP nick-end labeling, whereas induction of DNA repair was evaluated by GADD-153 expression. A baseline level for proliferation and damage was observed in cells from control animals that did not alter significantly during acute hyperoxia exposure. However, a rise in these markers was observed 24 h into recovery. Over 72 h of recovery, markers for proliferation remained elevated, whereas those for DNA damage and repair peaked at 48 h and then returned back to baseline. The expression of GADD-153 followed a distinct course, rising significantly during acute exposure and peaking at 48 h recovery. These data demonstrate that in healthy, adult male C57BL/6J mice, AEC2 proliferation, damage, and repair follow separate courses during hyperoxia recovery and that both proliferation and efficient repair may be required to ensure AEC2 survival.
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PMID:Contribution of proliferation and DNA damage repair to alveolar epithelial type 2 cell recovery from hyperoxia. 1629 57


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