Adipose triglyceride lipase–mediated lipid catabolism is essential for bronchiolar regeneration
Manu Manjunath Kanti, … , Gerald Hoefler, Paul Willibald Vesely
Manu Manjunath Kanti, … , Gerald Hoefler, Paul Willibald Vesely
Published March 29, 2022
Citation Information: JCI Insight. 2022;7(9):e149438. https://doi.org/10.1172/jci.insight.149438.
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Research Article Metabolism Pulmonology

Adipose triglyceride lipase–mediated lipid catabolism is essential for bronchiolar regeneration

Abstract

The lung airways are constantly exposed to inhaled toxic substances, resulting in cellular damage that is repaired by local expansion of resident bronchiolar epithelial club cells. Disturbed bronchiolar epithelial damage repair lies at the core of many prevalent lung diseases, including chronic obstructive pulmonary disease, asthma, pulmonary fibrosis, and lung cancer. However, it is still not known how bronchiolar club cell energy metabolism contributes to this process. Here, we show that adipose triglyceride lipase (ATGL), the rate-limiting enzyme for intracellular lipolysis, is critical for normal club cell function in mice. Deletion of the gene encoding ATGL, Pnpla2 (also known as Atgl), induced substantial triglyceride accumulation, decreased mitochondrial numbers, and decreased mitochondrial respiration in club cells. This defect manifested as bronchiolar epithelial thickening and increased airway resistance under baseline conditions. After naphthalene‑induced epithelial denudation, a regenerative defect was apparent. Mechanistically, dysfunctional PPARα lipid-signaling underlies this phenotype because (a) ATGL was needed for PPARα lipid-signaling in regenerating bronchioles and (b) administration of the specific PPARα agonist WY14643 restored normal bronchiolar club cell ultrastructure and regenerative potential. Our data emphasize the importance of the cellular energy metabolism for lung epithelial regeneration and highlight the significance of ATGL-mediated lipid catabolism for lung health.

Authors

Manu Manjunath Kanti, Isabelle Striessnig-Bina, Beatrix Irene Wieser, Silvia Schauer, Gerd Leitinger, Thomas O. Eichmann, Martina Schweiger, Margit Winkler, Elke Winter, Andrea Lana, Iris Kufferath, Leigh Matthew Marsh, Grazyna Kwapiszewska, Rudolf Zechner, Gerald Hoefler, Paul Willibald Vesely

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Figure 1

Airways of Atgl-KO/cTg mice show triglyceride accumulation and elevated breathing resistance.

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Airways of Atgl-KO/cTg mice show triglyceride accumulation and elevated ...
(A) Representative bronchioles in lung sections from control and Atgl‑KO/cTg mice stained with ORO. Scatter plots report data on triglyceride (TG) in lung tissues (n = 3 mice/group), and TGH activity in club cell isolates. The ATGL inhibitor Atglistatin was present if indicated. n = 3 experiments per group. We used 1-way ANOVA with Bonferroni’s test for multiple comparisons. (B) In situ Atgl: Images of lung sections incubated with Atgl mRNA–specific probes. Arrowheads depict representative hybridization signals. The scatter plot shows Atgl mRNA expression in LCM bronchioles determined by qPCR and normalized to 18S rRNA. n = 4 mice/group. (C) Representative H&E sections. Images were computationally modified to illustrate the bronchiolar height measurement process. Scatter plots report data on bronchiolar epithelial height of airways (n = 9 control mice and n = 8 Atgl-KO/cTg mice). Airway function parameters, resistance and compliance, were measured using a computer-controlled piston ventilator (n = 6 mice/group). Animals were aged 6 to 9 months. Error bars depict SEM. Statistical analysis was performed with Student’s 2-tailed t test. The outlier (gray) was detected using Grubb’s test (α = 0.05).Scale bars: 20 μm. Detailed information on animals is provided in Supplemental Table 1.