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Acute exposure to hyperoxia results in well-described pathophysiologic responses in the lungs, beginning with subtle, subcellular changes and ending with severe pulmonary inflammation and edema. The biologic events that underlie or accompany this injury are not well understood. Our previous studies in rabbits have shown that hyperoxia induces large increases in the mRNAs encoding metallothionein (MT) and the tissue inhibitor of metalloproteinases (TIMP-I). Here we report studies of hyperoxic lung injury in two strains of mouse that differ in their relative resistance to O2 toxicity. O2-sensitive (C57BL/6J) mice and O2-resistant (C3H/HeJ) mice were exposed to 100% O2 for up to 96 h. Lung mRNAs were assayed by primer extension and slot blot hybridization. By 72 h of hyperoxia, the sensitive strain showed large increases in MT-I, MT-II, and TIMP-I mRNAs. The resistant strain showed similar changes but with a 24-h delay. In situ hybridization demonstrated that hyperoxic lung injury was accompanied by obvious increases in TIMP-I and MT transcripts in cells surrounding arteries and large airways, where many inflammatory cells were localized. With prolonged exposure, hybridization to MT transcripts had spread throughout lung parenchyma. The two strains showed the same patterns of in situ hybridization for TIMP-I and MT transcripts but, as with the whole lung homogenates, followed a different time course. Corresponding increases in MT protein were shown to occur, using a cadmium binding assay and by immunohistochemistry. The strong spatial correlation between the presence of localized inflammation and increased TIMP-I and MT expression further supports the importance of TIMP-I and MT in acute lung injury.
Am J Respir Cell Mol Biol 1994 Feb
PMID:Increased expression of tissue inhibitor of metalloproteinases (TIMP-I) and metallothionein in murine lungs after hyperoxic exposure. 811 Apr 67

Recently, we demonstrated that chronic exposure to hyperoxia causes in vivo airway muscarinic receptor hyperresponsiveness in the developing rat [Am. J. Physiol. 262 (Lung Cell. Mol. Physiol. 6): L263-L269, 1992]. To test whether airway cholinergic hyperresponsiveness might result from intrinsic alterations in smooth muscle contractility, we measured the effect of in vivo hyperoxia on the contractile force elicited by acetylcholine (ACh) of isometrically mounted tracheal rings in vitro. Tracheal rings were obtained from 3-wk-old rats exposed to air or to > 95% O2 for 8 days. Muscarinic responses were determined by measuring the force elicited by exposure to increasing concentrations of ACh. Responses were normalized to the morphometrically determined tracheal smooth muscle cross-sectional area in a plane perpendicular to the axis of force generation. In vivo O2 exposure significantly increased maximal ACh-induced stress generation (response to 10(-3) M ACh: air, 15.92 +/- 1.37 g/mm2; O2, 21.78 +/- 1.52 g/mm2; P = 0.010). The ACh-induced stress generation of cylinders from hyperoxic rats was substantially reduced by both epithelial removal and treatment with the cyclooxygenase inhibitor indomethacin. We conclude that in vivo hyperoxic exposure increases tracheal smooth muscle contractile function in vitro and that epithelium-derived prostaglandin(s) contributes to the observed increase in maximal contractile responsiveness.
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PMID:Exposure of immature rats to hyperoxia increases tracheal smooth muscle stress generation in vitro. 817 85

Exposure of cell cultures to hyperoxia, i.e., an atmosphere containing more than 20% O2, results in various genotoxic effects. The most prominent effect of hyperoxia is its clastogenicity. In this paper, earlier published data, obtained from research devoted to the mechanism of hyperoxia-induced clastogenesis, are reviewed. In addition, new data are presented concerning the hyperoxia-sensitivity of the DNA-repair deficient Chinese hamster cell lines xrs1, irs1, and EM9. None of these ionizing radiation-sensitive mutants showed hypersensitivity to hyperoxia, as measured by chromosomal aberration induction and loss of clonogenic cell survival. From the normal hyperoxia-sensitivity of xrs1, it may be concluded that DNA double strand breaks, of the type that are induced by ionizing radiation, do not play a role in chromosomal aberration formation by hyperoxia. In addition, since xrs1 is hypersensitive to drugs that inhibit topoisomerase II, it seems rather unlikely that exposure to hyperoxia affects topoisomerase II activity. Based on circumstantial evidence we hypothesize that perturbation of poly(ADP-ribose) metabolism may play a critical role in the mechanism of hyperoxia-induced clastogenesis.
Environ Mol Mutagen 1993
PMID:Mechanism of hyperoxia-induced chromosomal breakage in Chinese hamster cells. 822 8

We have investigated factors that regulate hydrogen peroxide (H2O2) release from vascular endothelial cells. Endothelial cells produce H2O2 at an intracellular site in the vicinity of peroxisomes and at a second site near the cell surface that is inaccessible to intracellular catalase or glutathione peroxidase. Regulation of H2O2 generation at the intracellular site was studied using aminotriazole, which inactivates catalase in the presence of H2O2. Regulation of H2O2 generation at the second site was studied by measuring H2O2 release into the medium. The rate of H2O2 release was constant over 2 h when cells were incubated in room air. Changing O2 levels in the atmosphere from 0% to 10% O2 resulted in a threefold increase in the rate of H2O2 release. Elevation of O2 levels from 10% to 95% O2 produced no further enhancement in the rate of release. Preincubation of cells under hypoxic conditions did not lead to an exaggerated rate of H2O2 release when cells were returned to room air. Pretreatment of cells with exogenous H2O2 inhibited subsequent H2O2 release while pretreatment with catalase enhanced H2O2 release. Although arachidonic acid transiently enhanced the rate of H2O2 release through a mechanism dependent on PGH synthase, basal H2O2 release was independent of this enzyme. Neither hypoxia, hyperoxia, or hypoxia followed by reoxygenation altered H2O2 generation at the intracellular site accessible to peroxisomal catalase. These data demonstrate that H2O2 release from endothelial cells is responsive to changes in O2 concentrations over a narrow range. The mechanisms involved are subject to product inhibition and appear to be saturated at 10% O2 in the atmosphere.
Am J Respir Cell Mol Biol 1993 Dec
PMID:Modulation of hydrogen peroxide release from vascular endothelial cells by oxygen. 825 92

Null mutants for Cu/Zn superoxide dismutase (CuZnSOD) in Drosophila melanogaster are male sterile, have a greatly reduced adult life span, and are hypersensitive to paraquat. We have introduced a synthetic bovine CuZnSOD transgene under the transcriptional control of the D. melanogaster 5C actin promoter into a CuZnSOD-null mutant of D. melanogaster. This was carried out by P-element-mediated transformation of the Drosophila-bovine CuZnSOD transgene into a CuZnSOD+ recipient strain followed by genetic crossing of the transgene into a strain carrying the CuZnSOD-null mutation, cSODn108. The resulting transformants express bovine CuZnSOD exclusively to about 30% of normal Drosophila CuZnSOD levels. Expression of the Drosophila-bovine CuZnSOD transgene in the CuZnSOD-null mutant rescues male fertility and resistance to paraquat to apparently normal levels. However, adult life span is restored to only 30% of normal, and resistance to hyperoxia is 90% of that found in control flies. This striking differential restoration of pleiotropic phenotypes could be the result of a threshhold of CuZnSOD expression necessary for normal male fertility and resistance to the toxicity of paraquat or hyperoxia which is lower than the threshold required to sustain a normal adult life span. Alternatively, the differential rescue of fertility, resistance to active oxygen, and life span might indicate different cell-specific transcriptional requirements for these functions which are normally provided by the control elements of the native CuZnSOD gene but are only partly compensated for by the transcriptional control elements of the actin 5C promoter.
Mol Cell Biol 1994 Feb
PMID:Phenotypic rescue by a bovine transgene in a Cu/Zn superoxide dismutase-null mutant of Drosophila melanogaster. 828 9

The effect of a previous exposure to hyperbaric oxygen (HBO) on the synthesis capacity of prostaglandin (PG) and thromboxane (TX) was investigated in the brain of male rats. Three groups of rats were used: 1. Neurotoxic HBO (n = 11): The rats were exposed to sixfold the atmospheric pressure (101.3 kPa), i.e., 6 absolute atmospheres (ATA), of pure O2 up to the first convulsion (6 ATA O2); 2. Mild hyperoxia (n = 10): The rats were exposed to compressed air at the same absolute pressure and for a similar time than that of the neurotoxic HBO group (here PO2 is 1.26 ATA); 3. Normoxia at atmospheric pressure (PO2 is 0.21 ATA) for control. There was no convulsion in groups 2 and 3. Decompression of the high pressure groups lasted 15 min. After decapitation, samples of the frontal cortex and the striatum were taken, weighed, washed, and then incubated in Krebs-Ringer bicarbonate for 1 h. The release of eicosanoids in the medium was determined by enzyme immunoassay. Mild hyperoxia only significantly reduced in the striatum the release of 6-keto-PGF1 alpha (1.3 +/- 2.4 vs 10.9 +/- 6.6 pg/mg wet tissue, p < 0.001; mean +/- SD) and PGE2 (3.2 +/- 2.7 vs 7.8 +/- 6.5 pg/mg wet tissue, p < 0.05), whereas TXB2 did not change.(ABSTRACT TRUNCATED AT 250 WORDS)
Mol Chem Neuropathol 1993 Oct
PMID:Effect of hyperbaric oxygen on prostaglandin and thromboxane synthesis in the cortex and the striatum of rat brain. 829 21

Aerobic metabolism requires a continuous oxygen supply, which in turn can form partially reduced species (free radicals) that damage cellular components. To prevent this, organisms have elaborate free radical-scavenging defenses that include the superoxide dismutases. The lungs are unique in their role as an oxygen-gathering system, making these defenses critical to lung integrity. Manganese superoxide dismutase (Mn-SOD) levels increase in rats exposed to sublethal doses of hyperoxia and correlate with the development of tolerance to higher levels of hyperoxia. Although pulmonary Mn-SOD protein and mRNA levels both change with hyperoxia, the timing and levels differ dramatically. Lung heterogeneity makes extrapolation of data from whole tissue homogenates or cultures difficult. In this study, in situ hybridization of Mn-SOD in the lungs of adult rats exposed to air or to 85% O2 for 3 days was performed. In animals exposed to either air or 85% O2, Mn-SOD transcripts were present in arterioles, the septal tips of alveolar ducts, alveolar type II cells, and mesothelial cells. Hyperoxic lung had an intense, continuous labeling of the pleura that was distinctly greater than the intermittent labeling of the pleura found in control animals. The high level of expression of Mn-SOD mRNA in alveolar duct septal tips in both control and O2-exposed animals may be secondary to increased aerobic activity in these regions, which contain collagen and elastin and are important stress-bearing elements in the lung. Alveolar type II cells are metabolically active secretory cells and thus may experience increased endogenously generated oxidative stress. Pleural effusions are common after hyperoxic exposures, suggesting damage to the mesothelium.(ABSTRACT TRUNCATED AT 250 WORDS)
Am J Respir Cell Mol Biol 1993 May
PMID:Distribution of manganese superoxide dismutase mRNA in normal and hyperoxic rat lung. 848 Dec 34

Alveolar-capillary membrane remodeling, including microvessel wall thickening and interstitial fibrosis, is a well-known sequela of cell proliferation in the hyperoxia-injured lung. The array of growth molecules released locally that potentially mediate this response, and their cell(s) of origin, are currently being defined. To elucidate the role of tumor necrosis factor alpha (TNF alpha), an effector molecule of cell injury and proliferation, and the role of the alveolar macrophage (AM) as its source during the acute (1 to 24 h) and chronic stages (3 to 28 days) of hyperoxia-induced injury, we have analyzed gene and protein expression in cells recovered from rat lung by bronchoalveolar lavage. In the hyperoxic lung, cell number was similar to that in normal lung (1 x 10(6)) except on day 7, when it was higher (5 x 10(6)). Virtually all cells recovered from the normal and hyperoxic lung were AMs, with the exception that on days 3 and 7 of hyperoxia these cells represented 69% and 55% of the population, respectively, and polymorphonuclear leukocytes and lymphocytes the remainder. Probe specificity was confirmed by detection of TNF alpha RNA (1.6 kb) from lung cells recovered after lipopolysaccharide (LPS) treatment (positive control) and from the hyperoxic lung (at day 3), with an extremely low level of constitutive expression detected in cells from normal lung. In cytospin preparations, TNF alpha mRNA transcripts were detected in few AMs recovered from normal lung and in most AMs after LPS treatment. In the hyperoxic lung, a signal was detected at 3 h, when approximately 25% of the population was positive. The number of hybridizing cells then increased, being highest on day 7 (day 1 approximately 30%, day 3 approximately 58%, day 7 approximately 90%, day 28 approximately 65%). No expression of TNF alpha protein was detected in AMs from normal lung; positive cells were detected in the hyperoxic lung from day 1 and thereafter. We conclude from upregulation of the TNF alpha gene in a significant number of cells, and from the increase in the number expressing biologically active protein, that AMs are an important source of this molecule both in the acute and chronic stages of hyperoxic lung injury. It is anticipated that an increased understanding of the cellular sources of mediators effecting vascular and alveolar wall remodeling in vivo will contribute to the development of strategies to inhibit the response.
Am J Respir Cell Mol Biol 1996 Jun
PMID:TNF alpha gene and protein expression in alveolar macrophages in acute and chronic hyperoxia-induced lung injury. 865 83

The epithelium of the alveolus and distal airway meets unique requirements, functioning as a gas exchange membrane and barrier to alveolar flooding by vascular contents as well as to bloodstream contamination by airborne toxins and pathogens. Gene products specifically expressed by this epithelium, notably the surfactant apoproteins, have had important clinical application. No cell surface antigen specific for alveolar type II and Clara cells has been described. We report the biochemical characterization, tissue and developmental expression, and upregulation by injury of a 172 kD protein recognized by a monoclonal antibody, 3F9, synthesized in response to immunization with freshly isolated rat alveolar type II cells. p172 is expressed in a polarized fashion by the apical surface of rat alveolar type II and Clara cells. An immunohistochemical survey of various rat tissues and organs reveals lung specificity. p172 is first detectable in rare epithelial cells at 19 days of gestation, a time when the fully differentiated alveolar type II cell is identified by the first detection of lamellar bodies. There is a dramatic increase in p172 expression just prior to birth. Hyperoxic lung injury results in increased expression of p172. The upregulation of p172 by hyperoxia and its cell-specific expression suggests an important adaptive function.
Am J Respir Cell Mol Biol 1996 Jun
PMID:p172: An alveolar type II and Clara cell specific protein with late developmental expression and upregulation by hyperoxic lung injury. 865 82

Using hyperoxia as a model of oxidant-induced lung injury in the rat, we explored the regulation of heme oxygenase-1 (HO-1) expression in vivo and in vitro. We demonstrate marked increase of HO-1 messenger ribonucleic acid (mRNA) levels in rat lungs after hyperoxia. Increased HO-1 mRNA expression correlated with increased HO-1 protein and enzyme activity. Immunohistochemical studies of the rat lung after hyperoxia showed increased HO-1 expression in a variety of cell types, including the bronchoalveolar epithelium and interstitial and inflammatory cells. We then examined the regulation of HO-1 expression in vitro after hyperoxia and observed increased HO-1 gene expression in various cultured cells including epithelial cells, fibroblasts, macrophages, and smooth muscle cells. Increased HO-1 mRNA expression correlated with increased HO-1 protein in vitro, and resulted from increased gene transcription and not from increased mRNA stability. We show that transcriptional activation of the HO-1 gene by hyperoxia requires cooperation between the HO-1 promoter and an enhancer fragment located 4 kb upstream from its transcription site. Increased HO-1 gene transcription was associated with increased activator protein-1 (AP-1) binding activity and supershift of the AP-1 complex by antibodies to c-Fos and c-Jun after hyperoxia. Taken together, our data suggest that AP-1 activation may represent one mechanism mediating hyperoxia-induced HO-1 gene transcription.
Am J Respir Cell Mol Biol 1996 Jun
PMID:Regulation of heme oxygenase-1 expression in vivo and in vitro in hyperoxic lung injury. 865 84

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