Mitophagy-dependent necroptosis contributes to the pathogenesis of COPD
Kenji Mizumura, … , Stefan W. Ryter, Augustine M.K. Choi
Kenji Mizumura, … , Stefan W. Ryter, Augustine M.K. Choi
Published August 1, 2014
Citation Information: J Clin Invest. 2014;124(9):3987-4003. https://doi.org/10.1172/JCI74985.
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Research Article Pulmonology

Mitophagy-dependent necroptosis contributes to the pathogenesis of COPD

Abstract

The pathogenesis of chronic obstructive pulmonary disease (COPD) remains unclear, but involves loss of alveolar surface area (emphysema) and airway inflammation (bronchitis) as the consequence of cigarette smoke (CS) exposure. Previously, we demonstrated that autophagy proteins promote lung epithelial cell death, airway dysfunction, and emphysema in response to CS; however, the underlying mechanisms have yet to be elucidated. Here, using cultured pulmonary epithelial cells and murine models, we demonstrated that CS causes mitochondrial dysfunction that is associated with a reduction of mitochondrial membrane potential. CS induced mitophagy, the autophagy-dependent elimination of mitochondria, through stabilization of the mitophagy regulator PINK1. CS caused cell death, which was reduced by administration of necrosis or necroptosis inhibitors. Genetic deficiency of PINK1 and the mitochondrial division/mitophagy inhibitor Mdivi-1 protected against CS-induced cell death and mitochondrial dysfunction in vitro and reduced the phosphorylation of MLKL, a substrate for RIP3 in the necroptosis pathway. Moreover, Pink1–/– mice were protected against mitochondrial dysfunction, airspace enlargement, and mucociliary clearance (MCC) disruption during CS exposure. Mdivi-1 treatment also ameliorated CS-induced MCC disruption in CS-exposed mice. In human COPD, lung epithelial cells displayed increased expression of PINK1 and RIP3. These findings implicate mitophagy-dependent necroptosis in lung emphysematous changes in response to CS exposure, suggesting that this pathway is a therapeutic target for COPD.

Authors

Kenji Mizumura, Suzanne M. Cloonan, Kiichi Nakahira, Abhiram R. Bhashyam, Morgan Cervo, Tohru Kitada, Kimberly Glass, Caroline A. Owen, Ashfaq Mahmood, George R. Washko, Shu Hashimoto, Stefan W. Ryter, Augustine M.K. Choi

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Figure 3

CSE induces mitophagy in pulmonary epithelial cells, which is regulated by PINK1.

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CSE induces mitophagy in pulmonary epithelial cells, which is regulated ...
(A) Representative mitochondrial morphology (original magnification, ×120) in Beas-2B cells treated with 20% CSE for the indicated times. Blue: Hoechst 33258 (nucleus), green: Tom20 (mitochondria) (A and D). Scale bars: 10 μm (A, B, and D). Areas outlined in yellow are enlarged in lower panels and in panels at right (scale bars: 2 μm) (A, B, and D). Cell border is outlined in white (A and D). White arrows show mitochondrial fission, and white arrowheads show perinuclear compaction of mitochondria (A and D). Histograms show quantification of cells exhibiting fission or perinuclear mitochondrial compaction. 100 cells per group were analyzed in 3 independent experiments. (B) Cumulative detection of mitophagy using mt-mKeima (original magnification, ×120). Beas-2B cells were transfected with mt-mKeima and treated with 20% CSE for 8 hours. Pseudo-red color indicates acidic puncta. Histogram shows the ratio of high (550:438) signal area (red) to total mitochondrial area. 30 cells per group were analyzed in 3 independent experiments. ex., excitation. (C) Beas-2B cells were treated with 20% CSE for 6 hours, followed by mitochondrial fractionation. Immunoblot analysis of PINK1 and ubiquitin in mitochondrial/cytosolic fractions. (D) Representative mitochondrial morphology (original magnification, ×144) in alveolar epithelial cells isolated from Pink1+/+ or Pink1–/– mice treated with 20% CSE for 4 hours. Image is representative of 5 images/slide; n = 3 slides/condition (A, B, and D). Data represent the mean ± SEM (A and B). **P < 0.01 by unpaired, 2-tailed Student’s t test (A and B) versus control (A).