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Alveolar injury and regeneration following deletion of ABCA3
Tara N. Rindler, Courtney A. Stockman, Alyssa L. Filuta, Kari M. Brown, John M. Snowball, Wenjia Zhou, Ruud Veldhuizen, Erika M. Zink, Sydney E. Dautel, Geremy Clair, Charles Ansong, Yan Xu, James P. Bridges, Jeffrey A. Whitsett
Tara N. Rindler, Courtney A. Stockman, Alyssa L. Filuta, Kari M. Brown, John M. Snowball, Wenjia Zhou, Ruud Veldhuizen, Erika M. Zink, Sydney E. Dautel, Geremy Clair, Charles Ansong, Yan Xu, James P. Bridges, Jeffrey A. Whitsett
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Research Article Pulmonology

Alveolar injury and regeneration following deletion of ABCA3

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Abstract

Adaptation to air breathing after birth is dependent upon the synthesis and secretion of pulmonary surfactant by alveolar type 2 (AT2) cells. Surfactant, a complex mixture of phospholipids and proteins, is secreted into the alveolus, where it reduces collapsing forces at the air-liquid interface to maintain lung volumes during the ventilatory cycle. ABCA3, an ATP-dependent Walker domain containing transport protein, is required for surfactant synthesis and lung function at birth. Mutations in ABCA3 cause severe surfactant deficiency and respiratory failure in newborn infants. We conditionally deleted the Abca3 gene in AT2 cells in the mature mouse lung. Loss of ABCA3 caused alveolar cell injury and respiratory failure. ABCA3-related lung dysfunction was associated with surfactant deficiency, inflammation, and alveolar-capillary leak. Extensive but incomplete deletion of ABCA3 caused alveolar injury and inflammation, and it initiated proliferation of progenitor cells, restoring ABCA3 expression, lung structure, and function. M2-like macrophages were recruited to sites of AT2 cell proliferation during the regenerative process and were present in lung tissue from patients with severe lung disease caused by mutations in ABCA3. The remarkable and selective regeneration of ABCA3-sufficient AT2 progenitor cells provides plausible approaches for future correction of ABCA3 and other genetic disorders associated with surfactant deficiency and acute interstitial lung disease.

Authors

Tara N. Rindler, Courtney A. Stockman, Alyssa L. Filuta, Kari M. Brown, John M. Snowball, Wenjia Zhou, Ruud Veldhuizen, Erika M. Zink, Sydney E. Dautel, Geremy Clair, Charles Ansong, Yan Xu, James P. Bridges, Jeffrey A. Whitsett

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Figure 8

Recruitment of M2-like macrophages in mouse and human ABCA3 deficiency.

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Recruitment of M2-like macrophages in mouse and human ABCA3 deficiency.
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(A) Arg1, Retnla, and Mrc1 were measured by reverse transcription PCR (RT-PCR). in whole lung from control and Abca3-cKO mice. Data represent Arg1, Retnla, and Mrc1 mRNA expression with dot plot overlay; n = 7–9 mice/group, *P < 0.05, **P < 0.001 compared with control as determined by 1-way ANOVA. (B and C) Flow cytometry was used to identify interstitial (F4/80+CD11b+) and alveolar (F4/80+CD11c+) macrophages from protease digested lungs of control and Abca3-cKO mice treated with tamoxifen for 4 days harvested at 2 weeks. Data are mean ± SEM, n = 4, unpaired 2-tailed Student’s t test. (D) Arg1, Retnla, and Mrc1 mRNA were measured by RT-PCR in isolated interstitial macrophages (F4/80+CD11b+) from pooled control and Abca3-cKO mice treated with tamoxifen for 4 days harvested at 2 weeks; n = 3 mice/group. (E and F) Representative confocal microscopy of the M2 macrophage marker CD206 (red) and the epithelial marker NKX2.1 (white) in Abca3-cKO mice (n = 3) and pathological tissues from infants with severe lung disease caused by mutations in the ABCA3 gene (n = 5 patients). Scale bars: 50 μm. Inset scale bars: 5 μm.

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