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An SFTPC BRICHOS mutant links epithelial ER stress and spontaneous lung fibrosis
Jeremy Katzen, Brandie D. Wagner, Alessandro Venosa, Meghan Kopp, Yaniv Tomer, Scott J. Russo, Alvis C. Headen, Maria C. Basil, James M. Stark, Surafel Mulugeta, Robin R. Deterding, Michael F. Beers
Jeremy Katzen, Brandie D. Wagner, Alessandro Venosa, Meghan Kopp, Yaniv Tomer, Scott J. Russo, Alvis C. Headen, Maria C. Basil, James M. Stark, Surafel Mulugeta, Robin R. Deterding, Michael F. Beers
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Research Article Pulmonology

An SFTPC BRICHOS mutant links epithelial ER stress and spontaneous lung fibrosis

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Abstract

Alveolar type 2 (AT2) cell endoplasmic reticulum (ER) stress is a prominent feature in adult and pediatric interstitial lung disease (ILD and ChILD), but in vivo models linking AT2 cell ER stress to ILD have been elusive. Based on a clinical ChILD case, we identified a critical cysteine residue in the surfactant protein C gene (SFTPC) BRICHOS domain whose mutation induced ER stress in vitro. To model this in vivo, we generated a knockin mouse model expressing a cysteine-to-glycine substitution at codon 121 (C121G) in the Sftpc gene. SftpcC121G expression during fetal development resulted in a toxic gain-of-function causing fatal postnatal respiratory failure from disrupted lung morphogenesis. Induced SftpcC121G expression in adult mice resulted in an ER-retained pro-protein causing AT2 cell ER stress. SftpcC121G AT2 cells were a source of cytokines expressed in concert with development of polycellular alveolitis. These cytokines were subsequently found in a high-dimensional proteomic screen of bronchoalveolar lavage fluid from ChILD patients with the same class of SFTPC mutations. Following alveolitis resolution, SftpcC121G mice developed spontaneous pulmonary fibrosis and restrictive lung impairment. This model provides proof of concept linking AT2 cell ER stress to fibrotic lung disease coupled with translationally relevant biomarkers.

Authors

Jeremy Katzen, Brandie D. Wagner, Alessandro Venosa, Meghan Kopp, Yaniv Tomer, Scott J. Russo, Alvis C. Headen, Maria C. Basil, James M. Stark, Surafel Mulugeta, Robin R. Deterding, Michael F. Beers

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Figure 4

Expression of the SP-C C121G pro-protein causes activation of multiple epithelial ER stress pathways and induces AT2 cell apoptosis.

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Expression of the SP-C C121G pro-protein causes activation of multiple e...
(A) qRT-PCR for BiP expression in purified AT2 cells from SftpcWT R26Cre controls and SftpcC121G/C121G R26Cre mice at 7 days after tamoxifen treatment. Data normalized to 18S RNA are expressed as fold change in BiP normalized to control mice. *P < 0.05 vs. control using unpaired 2-tailed t test. (B) Representative immunohistochemical staining for BiP in lung sections (magnification, ×20) from control and SftpcC121G/C121G R26Cre mice at 7 days after tamoxifen shows increased BiP staining in AT2 cells (inset magnification, ×60). (C) Western blotting of AT2 cell lysates at 7 days after tamoxifen for BiP, ATF6 (P90), ATF4, CHOP, and β-actin. (D) qRT-PCR for XBP1 splicing ratio in AT2 cells at 7 days after tamoxifen shows an increase in the spliced fraction in SftpcC121G/C121G R26Cre AT2 cells compared with controls. *P < 0.05 vs. control using unpaired 2-tailed t test. (E) Western blot (left) of AT2 cell lysates at 7 days after tamoxifen for phosphorylated JNK (P-JNK), total JNK (T-JNK), and β-actin. Densitometry ratio (right) of P-JNK/T-JNK, reveals increase in P-JNK in SftpcC121G/C121G R26Cre mice compared with control. *P < 0.05 vs. control using unpaired 2-tailed t test. (F) Representative ×20 fluorescence micrograph from SftpcC121G/C121G R26Cre lung 7 days after tamoxifen stained with proSP-C (red) and cleaved caspase-3 (green) (left). Dot plots of double-positive (cleaved caspase-3+/proSP-C+) cells expressed as a percentage of total proSP-C+ AT2 cells are shown with means and SEM (right). *P < 0.05 vs. control using unpaired 2-tailed t test.

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