Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0034063 (pulmonary edema)
10,665 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A major function of the alveolar epithelium is to keep the airspace free of fluid and preserve gas exchange. Since Na-K-ATPase is believed to be important in this process, we hypothesized that Na-K-ATPase in the rat lung would increase in response to acute lung injury with pulmonary edema. Na-K-ATPase localization, mRNA expression, and protein levels were determined in hyperoxic lung injury. Adult male rats were exposed to greater than 97% oxygen for 60 h followed by recovery in room air. At 60 h of hyperoxia, the wet-to-dry lung weights increased, consistent with edema. Within the alveolar capillary region, the sodium pump remained localized to the type II cell basolateral membrane by immunocytochemistry. By Northern blot analysis, the level of total lung mRNA expression of the alpha 1- and beta-subunits of Na-K-ATPase increased three- to fourfold during hyperoxia compared with unexposed rats. Total lung Na-K-ATPase membrane protein, visualized with a Western blot technique, appeared to increase by 24 h of hyperoxic insult when compared with levels in unexposed animals. The increase in sodium pump gene expression that occurs during hyperoxic insult, followed by an increase in sodium pump membrane protein, suggests that type II cells increase their Na-K-ATPase synthesis as an early response to pulmonary edema and/or hyperoxia.
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PMID:Upregulation of rat lung Na-K-ATPase during hyperoxic injury. 165 77

Lung liquid clearance, epithelial permeability for Na+, mannitol and albumin, as well as Na,K-ATPase activity in alveolar type 2 (AT2) cells were studied during the acute and the recovery phase of hyperoxic lung injury. Rats exposed to 100% oxygen for 64 h were studied at 0, 7 and 14 d after removal from the hyperoxic chamber and compared with control rats breathing room air. In the isolated-perfused, liquid-filled rat lung, the albumin flux from the perfusate into the air spaces increased immediately after the oxygen exposure (220 +/- 56 mg/h) and returned to control values (28 +/- 7 mg/h) after 7 and 14 d of recovery. The small solutes (Na+ and mannitol) flux across the alveolar epithelium normalized only after 14 d of recovery in room air. Active Na+ transport and lung liquid clearance were reduced by approximately 45% immediately after oxygen exposure when compared with control values, increased by approximately 56% above control values after 7 d of recovery, and returned to control values after 14 d of recovery. Paralleling these changes the Na,K-ATPase activity decreased by approximately 41% in AT2 cells isolated from rats after 64 h of breathing 100% O2 and increased by approximately 25% after the rats recovered in room air for 7 d. These results suggest that alveolar epithelial Na,K-ATPase may contribute in the recovery from the hyperoxic lung injury by participating in the clearance of lung edema.
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PMID:Lung liquid clearance and Na,K-ATPase during acute hyperoxia and recovery in rats. 755 75

Previous studies have suggested that recovery from pulmonary edema may be dependent on active sodium ion transport. Most of the data supporting this concept came from work done in isolated type II cells, isolated lung preparations, or in models of alveolar flooding. There is a limited amount of information regarding the role of active sodium ion transport in vivo. Furthermore, most of this information was obtained in one model of pulmonary edema, the hyperoxic lung injury model. The purpose of these experiments was then to measure the activity of the sodium-potassium-adenosinetriphosphatase (Na(+)-K(+)-ATPase), the active component of the sodium transport process and an indirect marker of active sodium transport, during recovery from thiourea-induced pulmonary edema in rats. Na(+)-K(+)-ATPase activity was significantly increased during recovery from lung edema. This increase could not be accounted for by the Na(+)-K(+)-ATPase activity present in inflammatory cells recruited in the lung by the injury process or by a direct impact of thiourea on the enzyme. Alveolar flooding, induced by instillation of a protein-containing solution into the airways of ventilated rats also increased the activity of Na(+)-K(+)-ATPase, suggesting that activation of the enzyme is probably secondary to either the presence of edema or the physiological consequences associated with edema. The quantity of lung Na(+)-K(+)-ATPase protein was also elevated during edema resolution, indicating that augmented synthesis of this enzyme underlies the increased enzyme activity observed. The quantity of Na(+)-K(+)-ATPase protein in alveolar type II cells was also significantly enhanced during recovery from edema, suggesting that these cells contribute to active sodium transport in vivo. The results of this study suggest that active sodium transport could participate in the resolution of pulmonary edema.
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PMID:Increase of lung sodium-potassium-ATPase activity during recovery from high-permeability pulmonary edema. 899 59

Alveolar fluid is resorbed using active Na+ transport primarily through basolateral sodium-potassium-adenosinetriphosphatase (Na-K-ATPase) and apical Na+ channels that are particularly dense on the alveolar type II (ATII) epithelial cells. During lung injury with pulmonary edema, continued or accelerated Na+ and fluid resorption is critical for a favorable outcome. However, little is known of how ATII cell Na+ transport is affected during injury. These experiments examined the effects of acute lung injury on ATII cell Na-K-ATPase activity and expression using an established model of rats exposed to 100% O(2) for 60 h. Na-K-ATPase activity of ATII cells isolated immediately after exposure was assessed by ouabain-sensitive (86)Rb+ uptake in intact cells and by ouabain-sensitive P(i) production by cell membranes. In the presence of 1 mM ouabain, ouabain-sensitive Rb+ uptake was not different between normoxic and hyperoxic cells, but the apparent Na-K-ATPase maximal velocity (Vmax) of hyperoxic cell membranes was 75 +/- 8% of normoxic membranes (P < 0.05). On Western blots of ATII cell membranes, alpha1-subunit protein significantly decreased with hyperoxia (35 +/- 9% of normoxia; P < 0.05), whereas the amounts of the beta-subunit were unchanged (P > 0.05). On Northern blots of ATII cell total RNA, steady-state levels of both the alpha1- and beta1-subunit mRNA increased after hyperoxia (alpha1 = 2.5 +/- 1.3-fold; beta1 = 4.6 +/- 2.5-fold). Thus despite hyperoxic decreases in Na-K-ATPase Vmax and the amount of alpha1-protein, Rb+ uptake by Na-K-ATPase in intact cells was unchanged. The mRNA levels, protein amounts, and enzyme activity did not respond in parallel to hyperoxic injury, and the activity in intact cells correlated best with the amounts of the beta-subunit, the limiting component in de novo pump assembly in many tissues.
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PMID:Effects of hyperoxia on type II cell Na-K-ATPase function and expression. 912 12

Sodium reabsorption by the amiloride-sensitive sodium channel of epithelial cells plays a crucial role in the management of ionic composition and fluid volume in the body. In the respiratory system, sodium transport is involved in the clearance of pulmonary edema and of liquid secreted during fetal life at birth. We have cloned a partial cDNA of the alpha subunit of the mouse amiloride-sensitive sodium channel (alpha mENaC). In the region of comparison, the mouse alpha subunit shows 92% identity at the DNA level and 95% identity at the amino acid level with the rat sequence. The kidneys, lungs, and distal colon are major sites of expression of a 3.5-kb alpha mENaC mRNA. During mouse development, alpha mENaC transcripts appear late during gestation (d 17.5) and are expressed continuously thereafter. In the distal colon, a short 1.2-kb mRNA deleted of the 5' part of the transcript is detected during gestation and is replaced gradually by the mature 3.5-kb transcript after birth. Alpha mENaC and alpha1 Na+-K+-ATPase mRNAs have an expression profile that is modulated similarly during development for a given tissue. The expression of alpha mENaC transcripts increases transiently in the lungs at birth (2.5-fold), as for alpha1 Na+-K+-ATPase mRNAs (1.5-fold), suggesting that the expression of several components of the sodium transport system is modulated in the lungs at that time. In the kidney, there is no significant increase of alpha mENaC and alpha1 Na+-K+-ATPase mRNAs in newborns.
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PMID:The alpha subunit of the epithelial sodium channel in the mouse: developmental regulation of its expression. 928 73

Pulmonary edema clearance is driven primarily by active sodium transport out of the alveoli, mediated predominantly by apical sodium channels and the basolateral NA,K-ATPase. We postulated that dopamine, analogous to its effects in other transporting epithelia, could regulate these sodium transport mechanisms and affect lung liquid clearance. We therefore studied the effects of dopamine on sodium transport and liquid clearance in isolated perfused rat lungs. Instillation of dopamine into the airways caused a dose-dependent increase in liquid clearance from isolated rat lungs of up to 33% above control values at 10(-8) to 10(-4) M concentrations. 10(-6) M amiloride, which selectively inhibits apical sodium channels, decreased basal liquid clearance by 34% but did not inhibit the dopamine-mediated stimulation of lung liquid clearance. Instillation of 10(-4) M amiloride into rat airways, which inhibits other sodium transport mechanisms non-selectively, decreased basal lung liquid clearance by 49% and inhibited the dopamine-mediated stimulation of lung liquid clearance. Perfusion of rat lungs with 5 x 10(-4) M ouabain to specifically inhibit Na,K-ATPase reduced both basal clearance (by 55%) and the dopamine-stimulated increase in lung fluid clearance. Conceivably, the stimulation of lung liquid clearance by dopamine is due to a modulation of Na,K-ATPase in the pulmonary epithelium.
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PMID:Dopamine stimulates sodium transport and liquid clearance in rat lung epithelium. 930 83

A reduced cation reabsorption across the alveolar epithelium decreases water reabsorption from the alveoli and could diminish clearing accumulated fluid. To test whether hypoxia restricts cation transport in alveolar epithelial cells, cation uptake was measured in rat lung alveolar type II pneumocytes (AII cells) in primary culture and in A549 cells exposed to normoxia and hypoxia. In AII and A549 cells, hypoxia caused a PO2-dependent inhibition of the Na-K pump, of Na-K-2Cl cotransport, and of total and amiloride-sensitive 22Na uptake. Nifedipine failed to prevent hypoxia-induced transport inhibition in both cell types. In A549 cells, the inhibition of the Na-K pump and Na-K-2Cl cotransport occurred within approximately 30 min of hypoxia, was stable >20 h, and was reversed by 2 h of reoxygenation. There was also a reduction in cell membrane-associated Na-K-ATPase and a decrease in Na-K-2Cl cotransport flux after full activation with calyculin A, indicating a decreased transport capacity. [14C]serine incorporation into cell proteins was reduced in hypoxic A549 cells, but inhibition of protein synthesis with cycloheximide did not reduce ion transport. In AII and A549 cells, ATP levels decreased slightly, and ADP and the ATP-to-ADP ratio were unchanged after 4 h of hypoxia. In A549 cells, lactate, intracellular Na, and intracellular K were unchanged. These results indicate that hypoxia inhibits apical Na entry pathways and the basolateral Na-K pump in A549 cells and rat AII pneumocytes in culture, indicating a hypoxia-induced reduction of transepithelial Na transport and water reabsorption by alveolar epithelium. If similar changes occur in vivo, the impaired cation transport across alveolar epithelial cells might contribute to the formation of hypoxic pulmonary edema.
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PMID:Impairment of cation transport in A549 cells and rat alveolar epithelial cells by hypoxia. 935 55

Previous studies in kidney, heart, and liver cells have demonstrated that dexamethasone regulates the expression of Na-K-ATPase. In the lungs, Na-K-ATPase has been reported in alveolar epithelial type II (ATII) cells and is thought to participate in active Na+ transport and lung edema clearance. The aim of this study was to determine whether Na-K-ATPase would be regulated by dexamethasone in cultured rat ATII cells. Regulation of the Na-K-ATPase by dexamethasone could lead to a greater understanding of its role in active Na+ transport and lung edema clearance. Rat ATII cells were isolated, plated for 24 h, and exposed to 10(-7) and 10(-8) M dexamethasone. These cells were harvested at 0, 3, 6, 12, and 24 h after dexamethasone exposure for determination of steady-state Na-K-ATPase mRNA transcript levels, protein expression, and function. The steady-state Na-K-ATPase beta1-mRNA transcript levels increased in ATII cells 6, 12, and 24 h after dexamethasone exposure (P < 0.05). However, the steady-state alpha1-mRNA transcript levels were unchanged. The protein expression for the alpha1- and beta1-subunits increased in ATII cells exposed to dexamethasone compared with controls in association with a temporal increase in Na-K-ATPase function after dexamethasone exposure. These results suggest that dexamethasone regulates Na-K-ATPase in ATII cells possibly by transcriptional, translational, and posttranslational mechanisms.
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PMID:Dexamethasone upregulates the Na-K-ATPase in rat alveolar epithelial cells. 935 58

Decrease in alveolar oxygen tension may induce acute lung injury with pulmonary edema. We investigated whether, in alveolar epithelial cells, expression and activity of epithelial sodium (Na) channels and Na,K-adenosine triphosphatase, the major components of transepithelial Na transport, were regulated by hypoxia. Exposure of cultured rat alveolar cells to 3% and 0% O2 for 18 h reduced Na channel activity estimated by amiloride-sensitive 22Na influx by 32% and 67%, respectively, whereas 5% O2 was without effect. The decrease in Na channel activity induced by 0% O2 was time-dependent, significant at 3 h of exposure and maximal at 12 and 18 h. It was associated with a time-dependent decline in the amount of mRNAs encoding the alpha-, beta-, and gamma-subunits of the rat epithelial Na channel (rENaC) and with a 42% decrease in alpha-rENaC protein synthesis as evaluated by immunoprecipitation after 18 h of exposure. The 0% O2 hypoxia also caused a time-dependent decrease in (1) ouabain-sensitive 86Rubidium influx in intact cells, (2) the maximal velocity of Na,K-ATPase on crude homogenates, and (3) alpha1- and beta1-Na,K-ATPase mRNA levels. Levels of rENaC and alpha1-Na,K-ATPase mRNA returned to control values within 48 h of reoxygenation, and this was associated with complete functional recovery. We conclude that hypoxia induced a downregulation of expression and activity of epithelial Na channels and Na,K-ATPase in alveolar cells. Subsequent decrease in Na reabsorption by alveolar epithelium could participate in the maintenance of hypoxia-induced alveolar edema.
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PMID:Hypoxia downregulates expression and activity of epithelial sodium channels in rat alveolar epithelial cells. 937 26

Active Na+ transport by the alveolar epithelium keeps alveoli relatively dry. Hyperoxia increases epithelial permeability, resulting in pulmonary edema. We sought to determine whether active Na+ resorption from the air spaces and Na-K-ATPase activity increased in rats exposed to > 95% O2 for 60 h. The permeability x surface area products for unidirectional resorption of alveolar [14C]sucrose (PSsucrose) and 22Na+ (PSNa+) were measured in isolated, perfused rat lungs immediately after hyperoxia and after 3 and 7 days of recovery in room air. At 60 h of hyperoxia, the mean PSsucrose and PSNa+ increased from 6.71 +/- 0.8 x 10(-5) to 12.6 +/- 1.6 x 10(-5) cm3/s (P = 0.029) and from 23.6 +/- 1.1 x 10(-5) to 31.0 +/- 1.6 x 10(-5) cm3/s (P < 0.008), respectively. However, the values in individual rats ranged widely from no change to nearly a fourfold increase. Subgroup analysis revealed that benzamil- or amiloride-sensitive (transcellular) PSNa+ was significantly reduced in the exposed lungs with normal PSsucrose but was maintained in the lungs with high PSsucrose. By day 3 of recovery, mean Na+ and sucrose fluxes returned to values similar to control. Na-K-ATPase membrane hydrolytic maximal velocity (Vmax) activity fell significantly immediately after hyperoxic exposure but recovered to normal values by day 3 of recovery. The Na-K-ATPase beta 1-subunit antigenic signal did not significantly change, whereas the alpha 1-subunit levels increased during recovery. In summary, there was a heterogeneous response of different rats to acute hyperoxia. Hyperoxia led to complex, nonparallel changes in Na+ pump antigenic protein, hydrolytic activity, and unidirectional active Na+ resorption. Active Na+ transport was differentially affected, depending on degree of injury, but permeability and transport normalized by day 3 of recovery.
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PMID:Hyperoxic effects on alveolar sodium resorption and lung Na-K-ATPase. 943 74


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