CFTR-rich ionocytes mediate chloride absorption across airway epithelia
Lei Lei, Soumba Traore, Guillermo S. Romano Ibarra, Philip H. Karp, Tayyab Rehman, David K. Meyerholz, Joseph Zabner, David A. Stoltz, Patrick L. Sinn, Michael J. Welsh, Paul B. McCray Jr., Ian M. Thornell
Lei Lei, Soumba Traore, Guillermo S. Romano Ibarra, Philip H. Karp, Tayyab Rehman, David K. Meyerholz, Joseph Zabner, David A. Stoltz, Patrick L. Sinn, Michael J. Welsh, Paul B. McCray Jr., Ian M. Thornell
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Research Article Cell biology Pulmonology

CFTR-rich ionocytes mediate chloride absorption across airway epithelia

Abstract

The volume and composition of a thin layer of liquid covering the airway surface defend the lung from inhaled pathogens and debris. Airway epithelia secrete Cl– into the airway surface liquid through cystic fibrosis transmembrane conductance regulator (CFTR) channels, thereby increasing the volume of airway surface liquid. The discovery that pulmonary ionocytes contain high levels of CFTR led us to predict that ionocytes drive secretion. However, we found the opposite. Elevating ionocyte abundance increased liquid absorption, whereas reducing ionocyte abundance increased secretion. In contrast to other airway epithelial cells, ionocytes contained barttin/Cl– channels in their basolateral membrane. Disrupting barttin/Cl– channel function impaired liquid absorption, and overexpressing barttin/Cl– channels increased absorption. Together, apical CFTR and basolateral barttin/Cl– channels provide an electrically conductive pathway for Cl– flow through ionocytes, and the transepithelial voltage generated by apical Na+ channels drives absorption. These findings indicate that ionocytes mediate liquid absorption, and secretory cells mediate liquid secretion. Segregating these counteracting activities to distinct cell types enables epithelia to precisely control the airway surface. Moreover, the divergent role of CFTR in ionocytes and secretory cells suggests that cystic fibrosis disrupts both liquid secretion and absorption.

Authors

Lei Lei, Soumba Traore, Guillermo S. Romano Ibarra, Philip H. Karp, Tayyab Rehman, David K. Meyerholz, Joseph Zabner, David A. Stoltz, Patrick L. Sinn, Michael J. Welsh, Paul B. McCray Jr., Ian M. Thornell

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Figure 4

FOXI1 expression increases CFTR-dependent transepithelial current flow.

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FOXI1 expression increases CFTR-dependent transepithelial current flow. ...
(AD) Increasing ionocyte abundance with FOXI1 overexpression increases transepithelial current flow; n = 13 human donors. (A) Transepithelial conductances (Gt) obtained from epithelia bathed in symmetrical solutions. (B) Example transepithelial current (It) recordings with the transepithelial voltage held at 0 mV. The basolateral [Cl] was reduced to drive passive Cl current into the cell through apical CFTR channels and out of the cell through any basolateral Cl channels (depicted in inset). F&I, forskolin and 3-isobutyl-1-methylxanthine. (C) CFTRinh-172–sensitive It data. (D) CFTRinh-172–sensitive Gt data. (EH) Decreasing ionocyte abundance by FOXI1 disruption decreases transepithelial current flow; n = 14 human donors. Panels EH are as described for panels AD. Data points connected by a line represent paired experiments from a single human donor, graph depicts mean ± standard deviation, and P values obtained from paired, 2-sided Student’s t tests are presented within the figure.