Influenza-mediated reduction of lung epithelial ion channel activity leads to dysregulated pulmonary fluid homeostasis
Jeffrey D. Brand, Ahmed Lazrak, John E. Trombley, Ren-Jay Shei, A. Timothy Adewale, Jennifer L. Tipper, Zhihong Yu, Amit R. Ashtekar, Steven M. Rowe, Sadis Matalon, Kevin S. Harrod
Jeffrey D. Brand, Ahmed Lazrak, John E. Trombley, Ren-Jay Shei, A. Timothy Adewale, Jennifer L. Tipper, Zhihong Yu, Amit R. Ashtekar, Steven M. Rowe, Sadis Matalon, Kevin S. Harrod
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Research Article Pulmonology Virology

Influenza-mediated reduction of lung epithelial ion channel activity leads to dysregulated pulmonary fluid homeostasis

Abstract

Severe influenza (IAV) infection can develop into bronchopneumonia and edema, leading to acquired respiratory distress syndrome (ARDS) and pathophysiology. Underlying causes for pulmonary edema and aberrant fluid regulation largely remain unknown, particularly regarding the role of viral-mediated mechanisms. Herein, we show that distinct IAV strains reduced the functions of the epithelial sodium channel (ENaC) and the cystic fibrosis transmembrane regulator (CFTR) in murine respiratory and alveolar epithelia in vivo, as assessed by measurements of nasal potential differences and single-cell electrophysiology. Reduced ion channel activity was distinctly limited to virally infected cells in vivo and not bystander uninfected lung epithelium. Multiple lines of evidence indicated ENaC and CFTR dysfunction during the acute infection period; however, only CFTR dysfunction persisted beyond the infection period. ENaC, CFTR, and Na,K-ATPase activities and protein levels were also reduced in virally infected human airway epithelial cells. Reduced ENaC and CFTR led to changes in airway surface liquid morphology of human tracheobronchial cultures and airways of IAV-infected mice. Pharmacologic correction of CFTR function ameliorated IAV-induced physiologic changes. These changes are consistent with mucous stasis and pulmonary edema; furthermore, they indicate that repurposing therapeutic interventions correcting CFTR dysfunction may be efficacious for treatment of IAV lung pathophysiology.

Authors

Jeffrey D. Brand, Ahmed Lazrak, John E. Trombley, Ren-Jay Shei, A. Timothy Adewale, Jennifer L. Tipper, Zhihong Yu, Amit R. Ashtekar, Steven M. Rowe, Sadis Matalon, Kevin S. Harrod

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Figure 2

IAV reduces ENaC single-channel activity in infected but not in uninfected cells.

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IAV reduces ENaC single-channel activity in infected but not in uninfect...
Mice were infected with 4,000 PFU of PR8ΔGFP, lungs were harvested 5 days p.i., and fresh 250 μM slices were prepared using a live tissue slicer from uninfected controls and infected animals as previously described (14). Slices were incubated in culture medium for 3–4 hours before ion channel activity was recorded from GFP+ and GFP- cells. Lung cryosections display widespread infection. GFP- cells exhibited single channels with conductance of 4 pS and 18 pS. Recordings were obtained at Vpatch + 100 mV when Vm was 0 mV (slices incubated in 135 mM KCl Ringer). Original magnification, ×100 (A) and ×200 (B). (C) Tracings of ENaC open probability conductance in GFP- cells. Histogram shown in D shows number of events for the 4 Ps channel only. (E) A representative recording of channel activities recorded from GFP+-infected AT2 cells. (F) GFP+ AT2 cells exhibited substantial reduction of 4 pS and 18 pS activity, without affecting their unitary conductances. Please see Figure 3 for quantification of these findings.