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Adenoviral-Mediated Overexpression of the NA,K-ATPase ß₁ Subunit Gene Increases Lung Edema Clearance and Improves Survival During Acute Hyperoxic Lung Injury in Rats^*

^* From the Section of Pulmonary and Critical Care Medicine, Michael Reese Hospital, and University of Illinois at Chicago, Chicago, IL.

Correspondence to: Phillip Factor, DO, FCCP, Pulmonary and Critical Care Medicine, Michael Reese Hospital and Medical Center, 2929 S Ellis, 314 Kunstader, Chicago, IL 60616; e-mail: PFACT{at}AOL.COM

Rats exposed to acute hyperoxia develop a lung injury characterized by pulmonary edema and decreased ability to clear lung liquid.^{1 2} Accumulating evidence indicates that active Na⁺ transport is an important contributor to lung edema clearance.^{3 4 5} In the alveolus, Na,K-adenosine triphosphatases (ATPases) have been shown to be responsible for active Na⁺ transport across the alveolar epithelium.^{3 5 6} These pumps works in concert with other epithelial transport proteins, including water and apical Na⁺ channels, to generate a transepithelial Na⁺ gradient that causes the movement of water out of the alveolar airspace.⁶

Na,K-ATPases are transmembrane heterodimers that are composed of and ß subunits.⁷ The subunit cleaves high-energy phosphate bonds and exchanges intracellular Na⁺ for extracellular K⁺. The smaller ß subunit is a glycosylated transmembrane molecule that controls /ß heterodimer assembly and insertion into the plasma membrane; its presence is required for normal Na,K-ATPase function. Alveolar type II epithelial cells and whole rat lungs express the ₁ and ß₁ subunits of this multigene family and the levels of their respective messenger RNAs and protein change in response to stimuli such as hyperoxia.^{2 8 9} It has been reported that rats exposed to acute hyperoxia have parallel changes in active Na⁺ transport and lung edema clearance.^{2 8 9} Specifically, decreased Na,K-ATPase expression is associated with decreased lung liquid clearance. Similar changes have been reported for an amiloride-sensitive apical Na⁺ channel.¹⁰ As a result of these studies, we hypothesized that adenoviral-mediated overexpression of Na,K-ATPase subunit proteins could improve lung liquid clearance during hyperoxic lung injury.

We have observed previously that adenoviral-mediated transfer of Na,K-ATPase subunit genes increases Na,K-ATPase messenger RNA and protein expression in rat and human alveolar epithelial cells.^{11 12 13} Na,K-ATPase function was increased by up to 250% following gene transfer in these in vitro experiments. We have also reported recently that tracheal instillation of 4 x 10⁹ plaque forming units of an adenovirus expressing a Na,K-ATPase ß₁ subunit gene (adß₁) significantly increased alveolar ß₁ protein expression and improved lung liquid clearance in normal rats.¹⁴ Instillation of an otherwise identical virus that expresses a rat ₁ complementary DNA (cDNA) (ad₁) did not alter lung liquid clearance. These prior results indicate that Na,K-ATPase function and lung liquid clearance can be improved via Na,K-ATPase subunit overexpression and that the ß₁ subunit may be rate limiting in the rat alveolar epithelium.

Our prior studies used replication-deficient human type 5 adenoviruses containing individual cDNAs for the ₁ and ß₁ subunits of rat Na,K-ATPase.¹³ These vectors employ the immediate-early cytomegalovirus promoter and the SV40 t intron polyadenylation signal. They were generated via homologous recombination of shuttle vectors containing Na,K-ATPase subunit cDNAs with a plasmid that contains the entire adenovirus type 5 genome (pJM17). Following homologous recombination, they were serially plaque-purified and expanded in 293 cells.

To study the effect of Na,K-ATPase overexpression on hyperoxic lung injury, we used 270- to 300-g adult, male Sprague-Dawley rats. Sedated, spontaneously breathing rats were intubated and given 4 x 10⁹ plaque forming units of the above-described adenoviruses. Virus was administered in four 200-µL aliquots of a vehicle composed of 50% diluent/50% surfactant (Survanta, Abbott Laboratories; Columbus, OH). Vehicle was delivered at 5-min intervals interspersed with 90° rotation of the animals between instillations. Immediately prior to each instillation, the thorax was compressed to force expiration. Following endotracheal instillation, compression was released, allowing the animals to take a forceful inspiration that facilitated distal dispersion of vehicle. Rats were allowed to recover for 7 days to allow resolution of adenoviral-related host responses. After recovery, they were placed in a thermally controlled environmental chamber and exposed to >95% O₂ for 64 h. Lung liquid clearance was then measured using a fluid-filled, isolated lung model that allows measurement of permeability for solutes and lung liquid clearance. This model employs the instillation of ²²Na⁺, ³H-mannitol and Evan's blue albumin into the airspace compartment.^{2 4} The vascular compartment is continually perfused at fixed left atrial and pulmonary artery pressures with a buffered solution containing fluorescein isothiocyanate-albumin. The lungs are placed in a "pleural bath"; pH and temperature are held constant over a 60-min experimental period. Changes in concentration of Evan's blue albumin are used to calculate alveolar liquid clearance. Movement of the tracers between compartments is used to measure alveolar permeability. Separate survival studies were conducted by exposing rats to > 95% O₂ for up to 14 days. Between 15 and 20 rats per group were studied; mortality was recorded at 12-h intervals. In all hyperoxia studies, the adß₁ and ad₁ groups were contrasted to untreated room air (room air control) and hyperoxic animals (hyperoxic control), vehicle without adenovirus (surfactant), and a similar virus containing no cDNA (adNull).

Lung liquid clearance in the room air control, hyperoxic control, and surfactant animals was 0.51 ± 0.06, 0.28 ± 0.10 mL/h, and 0.34 ± 0.05 mL/h, respectively. Liquid clearance was increased 3.3-fold in the adß₁ infected animals (0.93 ± 0.13 mL/h, p < 0.001 vs surfactant). Clearance was minimally increased in the adNull (0.56 ± 0.15 mL/h, p < 0.02 vs surfactant) but not in the ad₁ animals (0.37 ± 0.12 mL/h). As compared to room air controls, alveolar permeability for small solutes (Na⁺ and mannitol) was minimally increased in all hyperoxic animals. No difference in permeability for albumin was noted among the hyperoxic animals.

All of the adß₁ rats exposed to hyperoxia survived to the end of the 14-day experimental period (p < 0.0002 vs hyperoxic control). There were no significant differences in LD₅₀ values among the non-adß₁ groups. Overall survival for each of the groups was 100%, 31%, 25%, 25%, and 17% for adß₁, hyperoxic control, surfactant, adNull, and ad₁, respectively.

These results show that adenoviral-mediated overexpression of a Na,K-ATPase ß₁ subunit enhances lung edema clearance following acute hyperoxia. This increase occurred despite the increased alveolar permeability for small solutes. Overexpression of this subunit also markedly improved survival from a lung injury associated with a high mortality. These data suggest that the requisite mechanisms necessary for lung liquid clearance in the alveolar epithelium following hyperoxia can be restored via augmentation of a key component, the Na,K-ATPase ß₁ subunit. They also support our previous data that shows that the ß₁ subunit may be rate limiting in the alveolar epithelium. Our findings support the concept that Na,K-ATPase function and maintenance of lung edema clearance are important contributors to alveolar function in the presence of acute lung injury. Conceivably, gene transfer of Na,K-ATPase subunit genes may eventually prove useful for the treatment of acute lung injury.

Footnotes

Supported by the Research and Education Foundation of Michael Reese Hospital, American Heart Association of Metropolitan Chicago, American Lung Association of Chicago, and HL-48129.

References

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