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miR-205-5p drives endothelial dysfunction and senescence in pulmonary fibrosis
Giuseppe Muscato, Benjamin B. Roos, Sharonda Harris, Xiaoyu Tracy Cai, Gina Civettini, Enrico Sciacca, Ahmed A. Raslan, Alessandra Castaldi, Sharon Elliot, Marilyn K. Glassberg, Carlo Vancheri, Daniel J. Tschumperlin, Giovanni Ligresti, Nunzia Caporarello
Giuseppe Muscato, Benjamin B. Roos, Sharonda Harris, Xiaoyu Tracy Cai, Gina Civettini, Enrico Sciacca, Ahmed A. Raslan, Alessandra Castaldi, Sharon Elliot, Marilyn K. Glassberg, Carlo Vancheri, Daniel J. Tschumperlin, Giovanni Ligresti, Nunzia Caporarello
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Research Article Pulmonology Vascular biology

miR-205-5p drives endothelial dysfunction and senescence in pulmonary fibrosis

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Abstract

Idiopathic pulmonary fibrosis (IPF) is a fatal, aging-related disease characterized by persistent lung fibroblast activation, progressive lung scarring, and several vascular abnormalities. We have previously demonstrated that aging-associated vascular dysfunction drives maladaptive endothelial responses to injury and exacerbates lung fibrosis via secretion of profibrotic endothelial cell–derived factors. However, regulatory mechanisms governing endothelial dysfunction during progressive lung fibrosis remain poorly understood. Here, using preclinical mouse models of progressive lung fibrosis as well as human IPF lungs, we demonstrate that miR-205-5p was overexpressed in lung endothelial cells (ECs) from fibrotic lungs and coordinated gene expression programs implicated in endothelial dysfunction and progressive fibrosis. Mechanistically, miR-205-5p induced senescence in lung ECs, mirroring the senescent phenotype of IPF lung ECs. Consistently, conditioned medium derived from lung ECs overexpressing miR-205-5p promoted lung fibroblast activation. Importantly, miR-205-5p inhibition in IPF lung ECs attenuated endothelial senescence and limited paracrine fibroblast activation. Finally, inhibition of miR-205-5p in vivo preserved the pulmonary vascular network and attenuated lung fibrosis progression in aged mice challenged with bleomycin. Collectively, our findings support what we believe to be a novel connection among lung endothelial miR-205-5p, endothelial senescence, and profibrotic alteration of the endothelial secretome and highlight miR-205-5p inhibition as a potential therapeutic intervention for pulmonary fibrosis.

Authors

Giuseppe Muscato, Benjamin B. Roos, Sharonda Harris, Xiaoyu Tracy Cai, Gina Civettini, Enrico Sciacca, Ahmed A. Raslan, Alessandra Castaldi, Sharon Elliot, Marilyn K. Glassberg, Carlo Vancheri, Daniel J. Tschumperlin, Giovanni Ligresti, Nunzia Caporarello

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Figure 7

miR-205-5p inhibition attenuates IPF lung EC senescence and limits paracrine fibroblast activation.

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miR-205-5p inhibition attenuates IPF lung EC senescence and limits parac...
(A) Representative immunofluorescence images for Ki67 and DAPI in IPF lung ECs transfected with a negative miRNA inhibitor or miR-205-5p inhibitor. Arrows indicate Ki67+ nuclei. Scale bar: 20 μm. (B) Quantification of Ki67+ nuclei (normalized to DAPI) reveals a significant increase in miR-205-5p–inhibited IPF lung ECs versus control-transfected IPF cells. Data are shown as mean ± SD of n = 4 independent biological replicates (average of 3–5 images per replicate) and expressed as percentage over control. P values were calculated using Student’s t test. (C) Representative SA-β-gal staining images showing attenuated staining in miR-205-5p–inhibited IPF lung ECs. Scale bar: 20 μm. (D) Quantification of SA-β-gal–positive cells (over total DAPI-positive cells) showing reduction of SA-β-gal–positive cells in miR-205-5p–inhibited IPF lung ECs. Data are shown as mean ± SD of n = 3 independent biological replicates (average of 3–5 images per replicate), and P values were calculated using Student’s t test. (E) IPF lung ECs were transfected with a miRNA inhibitor negative control or a miR-205-5p inhibitor. Six hours after transfection, medium was changed to remove transfection reagents. After 3 days, conditioned medium (CM) was collected and applied to recipient quiescent human lung fibroblasts for 5 days (schematics created with a licensed version of BioRender.com). (F) Representative images of immunostaining for type I collagen in human lung fibroblasts that received CM from control IPF lung ECs or from IPF lung ECs after miR-205-5p inhibition. (G) Quantification of collagen I staining in E shows decreased collagen deposition in recipient human lung fibroblasts exposed to CM from IPF lung ECs upon inhibition of miR-205-5p. N = 8 independent biological replicates, each performed in triplicates. Scale bar: 20 μm. Data are expressed as mean ± SD, and P values were calculated using Student’s t test. *P < 0.05.

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