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)

To better understand the biochemical events accompanying lung alveolarization and development, we studied the specific activity of the cAMP-dependent protein kinase (PKA) and the type 2A protein phosphastase (PP2A), and the activity and protein content of the calcium- and lipid-dependent protein kinase (PKC) in cytosolic preparations of lungs. Lungs were obtained from rat pups on day 2 of life and on days 7, 14, and 27 from pups exposed to hyperoxia (> 95% O2, days 4-14; 65% O2 days 15-27) or normoxia from day 4 onwards. There were no significant changes in PKA specific activity with developmental age or hyperoxic exposure. PKC specific activity increased significantly (P < .05) in normoxic animals from day 2 (64 +/- 13.5 pmol phosphate released/min/mg protein) to day 14 (105 +/- 9). The increase was sustained to day 27. There was no effect on PKC activity due to hyperoxia alone (ANOVA). This increase in PKC activity was accompanied by an increase in the mass of the delta, epsilon and zeta isoforms of PKC in normoxic pups. The gamma isoform of PKC was undetectable in all samples whereas the alpha and beta isoforms were detectable but showed no changes with developmental age. PP2A specific activity increased significantly (P < .05) from 13.3 +/- 0.5 nmol phosphate released/min/mg protein on day 2 to 17.7 +/- 0.9 on day 7 in normoxic pups, then returned to day 2 level at advanced developmental age. Hyperoxia exposure prevented the increase in enzyme activity observed on day 7 in normoxic animals. These data suggest that protein phosphorylation may be one mechanism by which alveolarization is regulated in developing lungs.
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PMID:Effect of developmental age and hyperoxia exposure on kinase and phosphatase activities in newborn rat lungs. 963 55

Iron uptake by cells may increase the intracellular pool of prooxidant iron prior to storage of iron within ferritin. Because hyperoxia is toxic to alveolar macrophages (AM) via mechanisms involving oxidant stress, we hypothesized that iron uptake by AM might promote hyperoxia-induced injury. To assess this hypothesis, we cultured AM recovered from healthy volunteers under conditions of normoxia or hyperoxia (60% or 95% oxygen) in media of varying iron content, including control media (3 microM iron) and media supplemented with iron (FeCl3; total iron 10, 20, or 40 microM). AM injury was assessed by measuring release of lactate dehydrogenase (LDH), phagocytic activity for yeast, and cytosolic concentrations of calcium ([Ca2+]i) as determined by ratio image analysis of AM loaded with the fluorescent calcium probe indo-1. There was dose-dependent accumulation of iron and ferritin synthesis in AM exposed to iron-supplemented media. Exposure of AM to hyperoxia (60% and 95% oxygen, 18 h) in control media increased LDH release and impaired phagocytic activity for yeast; however, similar hyperoxic exposures in iron-supplemented media significantly increased the cells' LDH release and decreased phagocytosis. Exposure to 95% oxygen increased the [Ca2+]i of AM over 18 h, but similar exposure in iron-supplemented media induced greater increases in [Ca2+]i. As compared with exposure to normoxia, exposure to hyperoxia (60% and 95% oxygen) also decreased iron uptake and, to a greater extent, ferritin synthesis by AM in iron-supplemented media. These data suggest that: (1) iron uptake promotes hyperoxic injury to AM; and (2) hyperoxia impairs the capacity of AM to sequester iron in ferritin.
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PMID:Iron uptake promotes hyperoxic injury to alveolar macrophages. 987 25

The effects of nitric oxide (NO) and metalloproteinases (MMP-2 and MMP-9) in the pathogenesis of hyperoxia-induced lung damage in newborn rats were examined. Three-day-old rat pups were subjected to hyperoxia (> or = 95% O2) or room air for 7 and 14 days. Some animals were treated with NG-L-nitro-L-arginine methyl ester (L-NAME, 10 mg kg(-1), s.c., daily). Histology, morphometry, oedema, Ca2+-dependent and -independent NO synthase (NOS) activities, expression of NOS isoforms and the activities of MMP-2 and MMP-9 were measured in lungs of hyperoxic and control animals. Exposure of rats to hyperoxia for 7 days resulted in alveolar sac injury characterized by the presence of cellular debris, red cell extravasation and inflammatory infiltration with mononuclear cells. Lung water content, epithelial, smooth muscle layers and total airway thickness was similar to controls. In contrast, exposure of rats to hyperoxia for 14 days resulted in lung oedema, inflammation and epithelial proliferation. Hyperoxia caused a decrease in Ca2+-dependent NOS activity, an effect that was associated with increased expression of eNOS protein. In control rats, Ca2+-dependent NOS activity and expression of eNOS were reduced at 14 days. Hyperoxia caused 10 fold increase in the activity of Ca2+-independent NOS that remained significantly elevated after 14 days of exposure to hyperoxia. The activity of this enzyme was unchanged in control rats. In lungs of hyperoxic rats, the immunoblot showed time-dependent, biphasic expression (peak at 7 days) of iNOS. The profile of expression of iNOS in control rats was similar. The activities of MMPs were increased in lungs of hyperoxic animals. The L-NAME treatment of hyperoxic animals reduced lung oedema and epithelial proliferation, but enhanced the activities of MMPs. L-NAME exerted no significant effects in control rats. It is concluded that increased generation of NO contributes to the pathogenesis of hyperoxia-induced lung damage in newborn rats.
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PMID:The role of nitric oxide and metalloproteinases in the pathogenesis of hyperoxia-induced lung injury in newborn rats. 988 73

Breathing air with a high oxygen tension induces an inflammatory response and injures the microvessels of the lung. The resulting development of smooth muscle cells in these segments contributes to changes in vasoreactivity and increased pulmonary artery pressure. This in vivo study determines the temporal and spatial expression of endogenous endothelial nitric oxide synthase (NOS III) and inducible NOS (NOS II), important enzymes regulating vasoreactivity and inflammation, in the adult rat lung during the development of experimental pulmonary hypertension induced by oxidant injury. We analyzed the cellular distribution of these NOS isoforms, using specific antibodies, and assessed enzyme activity at baseline and after 1-28 days of hyperoxia (FIO2 0.87). The number of NOS III-immuno-positive endothelial cells increased early in hyperoxia and then remained high. By day 28, the relative number of these cells had increased from 40% in proximal vessels and 13-16% in distal alveolar vessels of the normal lung to 73-86% and 40-59%, respectively, in hyperoxia. Pulmonary alveolar macrophages (PAMs), normally few in number and only weakly immunopositive for NOS II or III in the normal lung, increased in number in hyperoxia and were strongly immunopositive for each isoform. These morphological data were supported by a temporal increase in total and calcium-independent NOS activity. Thus NOS expression and activity significantly increased in hyperoxia as pulmonary hypertension developed, and NOS III expression increased selectively in vascular endothelial cells, while both NOS isoforms were expressed by the PAM population. We conclude that this increase in expression of a potent vasodilator, an antiproliferative agent for smooth muscle cells, and an antioxidant molecule represents an adaptive response to protect the lung from oxidant-induced vascular and epithelial injury.
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PMID:Expression of nitric oxide synthase isoforms (NOS II and NOS III) in adult rat lung in hyperoxic pulmonary hypertension. 993 78

Cyclosporin A (CsA), an inhibitor of protein phosphatase 2B (calcineurin), has been shown to play a role in exocytosis and neutrophil mobility. Hyperoxia (>95% oxygen for 72 h) causes lung injury and reduces lung compliance. This model is indicative of deficiencies in surfactant and elicits a vigorous immune response leading to further damage. We examined the effects of CsA on surfactant-secreting lung alveolar type II cells. CsA enhances ATP-stimulated increases in whole cell capacitance in the presence of 2 mM extracellular Ca2+. This measurement corresponds with increases in exocytosis. Because of its effect on the immune system and exocytosis from type II cells, CsA was examined for its protective effects against hyperoxia-induced lung damage in mice. We found that CsA (50 mg. kg-1. day-1) attenuated hyperoxia-induced reductions in lung compliance when administered before or during 72 h of >95% oxygen (P < 0.05). CsA (10 mg. kg-1. day-1) also had a protective effect against hyperoxia-induced changes in neutrophil infiltration, capillary congestion, edema, and hyaline membrane formation. Wet lung weight-to-dry lung weight ratios did not show any significant changes after hyperoxia or hyperoxia plus CsA (P < 0. 05). CsA may be useful to treat patients undergoing prolonged high-oxygen therapy and possibly other lung injuries.
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PMID:Cyclosporin A protects lung function from hyperoxic damage. 1033 35

The carotid body chemoreceptors, the major hypoxia sensory organs for the respiratory system, undergo a significant increase in their hypoxia responsiveness in the postnatal period. This is manifest by a higher level of afferent nerve activity for a given level of arterial oxygen tension. The mechanism for the enhanced sensitivity is unresolved, but most work has focused on the glomus cell, a secretory cell apposed to the afferent nerve ending and believed to be the site of hypoxia transduction. The glomus cell secretory response to hypoxia increases postnatally, and this is correlated with an enhanced calcium rise in response to hypoxia and an increase in oxygen-sensitive potassium currents. These changes are sensitive to the level of hypoxia in the postnatal period, and significant impairment of organ function is observed with postnatal hypoxia as well as postnatal hyperoxia. Although many questions remain, especially with regard to the coupling of glomus cells to nerve endings, the use of cellular and molecular techniques should offer resolution in the near future.
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PMID:Developmental aspects of oxygen sensing by the carotid body. 1084 48

This article describes the experimental infrastructure and subsequent successful clinical application of a comprehensive bypass and cardioplegic strategy that limits intraoperative injury and improves postoperative outcomes in pediatric patients. The infant heart is at high risk of damage from poor protection because of preoperative hypertrophy, cyanosis, and ischemia. The background factors of vulnerability to damage caused by cyanosis and ischemia are discussed, together with studies of the infrastructure of strategies to use normoxia versus hyperoxia as bypass starts, white blood cell filtration, warm induction and reperfusion with substrate enhancements, multidose blood cardioplegia, and an integrated approach to allow ischemia only when vision is needed in pediatric surgeries. Data on cardioplegic management, including reducing calcium, increasing magnesium, and reducing perfusion pressure are shown, as used during this technique. These principles were applied to a consecutive series of 567 patients at the Heart Institute for Children and University of Illinois hospital over a 2-year period. Included also were 72 patients with hypoplastic left heart over a 4-year period with this myocardial management strategy. Application of these concepts may improve the safety of protection in infant hearts.
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PMID:Pediatric myocardial protection: an overview. 1130 28

Neutrophil influx in lung injury is controlled in part by chemokines acting through the receptor, CXCR2. To avoid adverse effects of steroids typically used to modify inflammation, we evaluated the effects of competitive blockade of CXCR2 in rats on neutrophil function in vitro and on neutrophil influx in vivo in hyperoxia-induced newborn lung injury, a model of bronchopulmonary dysplasia. In vitro, SB-265610 antagonizes rat cytokine-induced neutrophil chemoattractant-1 (CINC-1)-induced calcium mobilization, IC50 = 3.7 nM, and rat neutrophil chemotaxis in a concentration-dependent manner, IC50 = 70 nM. In vivo, newborn rats exposed to 95% O2 for 8 days had increased lung neutrophil content. Injection with 1 to 3 mg/kg SB-265610 on days 3 to 5 reduced hyperoxia-induced neutrophil accumulation in bronchoalveolar lavage and whole lung myeloperoxidase accumulation at the highest doses. To determine whether these effects might be due in part to increased neutrophil apoptosis, peripheral neutrophils were cultured with and without SB-265610. Apoptosis was assessed by morphology, viability, and terminal transferase deoxyuridine triphosphatidyl nucleotide nick-end labeling. Treatment of neutrophils with CINC-1 reduced apoptosis compared with untreated neutrophils. SB-265610 reduced the antiapoptotic effect of CINC-1 to the levels of those untreated with CINC-1. A selective CXCR2 antagonist may be useful in diseases where neutrophil-mediated exacerbation is present.
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PMID:Nonpeptide CXCR2 antagonist prevents neutrophil accumulation in hyperoxia-exposed newborn rats. 1156 Oct 67

Chemotransduction of arterial hypoxemia by the cat carotid body is generally thought to begin with a hypoxia-induced depolarization of the glomus cells (GCs) of the carotid body (CB). This depolarization activates voltage-gated calcium channels with the subsequent entry of calcium, movement of transmitter-containing vesicles to the synaptic-like juncture between the GC and apposed sensory afferent neuron. The vesicles exocytotically release their transmitters which then proceed to the receptors on both the postsynaptic neuron and on the GCs themselves (autoreceptors). Action potentials and their modulation in the sensory fibers are the result, along with the modulation of further neurotransmitter release from the GCs. The purpose of the present study was to: (1) determine the parameters of an incubated cat CB preparation capable of releasing measurable amounts of catecholamines (CAs) in response to hypoxia; (2) determine the impact of muscarinic activities on CA release during the hypoxic challenge; (3) determine if the muscarinic activity preferentially modified the release of one CA more than another; (4) determine if there were any differences in the pattern of hypoxia-induced release of dopamine (DA) vs. norepinephrine (NE). CBs were harvested from deeply anesthetized cats. Cleaned of fat and connective tissue, they were incubated in Krebs Ringer bicarbonate solution at 37 degrees C, and bubbled with a hyperoxic mixture of gases (95% O(2)-5% CO(2)) for 30 min. The first series of experiments to address the CB's hypoxia-induced release of CAs explored the effects of incubating CBs for 2 h with hyperoxia vs. normoxia (21% O(2)-6% CO(2)) followed by a 30 min hypoxic challenge, with or without L-dihydroxyphenylalanine (L-DOPA). In the second series of experiments the CBs, after the first 30 min of hyperoxia, were next challenged with hypoxia (4% O(2)-5% CO(2)) for intervals of 3-20 min with intervening recovery periods of hyperoxia to determine the effect of the duration of the hypoxic exposure on CA release. In the third series of experiments the CBs, after the first 30 min of hyperoxia, were challenged with hypoxia for intervals of 10-40 min in the presence or absence of an M1 or M2 muscarinic receptor antagonist. CAs released into the incubation medium were analyzed by means of high performance liquid chromatography-electrochemical detection using standard procedures. Incubated cat CBs challenged for 2 h with hyperoxia followed by 30 min of hypoxia, released much more measurable amounts of CAs in the presence of 40 microM L-DOPA than without it. Moving from hyperoxia to hypoxia produced a better yield than moving from normoxia to hypoxia, and at least 10-20 min exposures were needed for measurable amounts of CAs. The M1 muscarinic receptor antagonist, pirenzepine, reduced the hypoxia-induced release of CAs during each exposure. Further, the reduction appeared to be dose-related. The M2 muscarinic receptor antagonist, methoctramine, enhanced the hypoxia-induced release of CAs during each exposure. These data support a role for acetylcholine (ACh) in the hypoxia-induced release of CAs, and suggest a significant, if modest, muscarinic dimension to it. And although hypoxia induced a greater release of DA than of NE, the muscarinic modulation of the release (both decreasing it and increasing it) may have had a greater impact on NE release than on DA release. Finally, the patterns of hypoxia-induced release of DA and NE from incubated cat carotid bodies are significantly different.
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PMID:Muscarinic modulation of hypoxia-induced release of catecholamines from the cat carotid body. 1182 Oct 6

It is well established that altering O2 delivery to contracting skeletal muscle affects human performance. In this respect, a reduced O2 supply (e.g., hypoxia) increases the rate of muscle fatigue, whereas increasing O2 supply (e.g., hyperoxia) reduces the rate of fatigue. Interestingly, the faster onset of fatigue in moderate hypoxia does not appear to be a consequence of mitochondrial O2 limitation because these effects occur at submaximal rates of O2 consumption for these conditions and at O2 tensions well above that which impairs mitochondrial O2 uptake in vitro. Alterations in O2 supply modulate the regulation of cellular respiration and may affect the onset of impaired Ca2+ handling with fatigue. Specifically, changes in O2 supply alter the coupling between phosphocreatine hydrolysis and O2 uptake in contracting muscles, which by determining the rate of inorganic phosphate (Pi) accumulation may affect Ca2+ release. Partial ischemia differs somewhat in that the reduction in force could be due to reduced O2 supply and/or impaired removal of metabolic by-products secondary to insufficient blood flow. Nonetheless, recent evidence shows a parallel decline and restoration of force with alterations in O2 supply but not blood flow alone during submaximal contractions. Furthermore, the causes of fatigue are similar when O2 is plentiful and when it is reduced.
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PMID:The role of O2 supply in muscle fatigue. 1188 Jun 91


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