Syndecan-1 promotes lung fibrosis by regulating epithelial reprogramming through extracellular vesicles
Tanyalak Parimon, Changfu Yao, David M. Habiel, Lingyin Ge, Stephanie A. Bora, Rena Brauer, Christopher M. Evans, Ting Xie, Felix Alonso-Valenteen, Lali K. Medina-Kauwe, Dianhua Jiang, Paul W. Noble, Cory M. Hogaboam, Nan Deng, Olivier Burgy, Travis J. Antes, Melanie Königshoff, Barry R. Stripp, Sina A. Gharib, Peter Chen
Tanyalak Parimon, Changfu Yao, David M. Habiel, Lingyin Ge, Stephanie A. Bora, Rena Brauer, Christopher M. Evans, Ting Xie, Felix Alonso-Valenteen, Lali K. Medina-Kauwe, Dianhua Jiang, Paul W. Noble, Cory M. Hogaboam, Nan Deng, Olivier Burgy, Travis J. Antes, Melanie Königshoff, Barry R. Stripp, Sina A. Gharib, Peter Chen
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Research Article Pulmonology

Syndecan-1 promotes lung fibrosis by regulating epithelial reprogramming through extracellular vesicles

Abstract

Idiopathic pulmonary fibrosis (IPF) is a chronic and fatal lung disease. A maladaptive epithelium due to chronic injury is a prominent feature and contributor to pathogenic cellular communication in IPF. Recent data highlight the concept of a “reprogrammed” lung epithelium as critical in the development of lung fibrosis. Extracellular vesicles (EVs) are potent mediators of cellular crosstalk, and recent evidence supports their role in lung pathologies, such as IPF. Here, we demonstrate that syndecan-1 is overexpressed by the epithelium in the lungs of patients with IPF and in murine models after bleomycin injury. Moreover, we find that syndecan-1 is a profibrotic signal that alters alveolar type II cell phenotypes by augmenting TGF-β and Wnt signaling among other profibrotic pathways. Importantly, we demonstrate that syndecan-1 controls the packaging of several antifibrotic microRNAs into EVs that have broad effects over several fibrogenic signaling networks as a mechanism of regulating epithelial plasticity and pulmonary fibrosis. Collectively, our work reveals new insight into how EVs orchestrate cellular signals that promote lung fibrosis and demonstrate the importance of syndecan-1 in coordinating these programs.

Authors

Tanyalak Parimon, Changfu Yao, David M. Habiel, Lingyin Ge, Stephanie A. Bora, Rena Brauer, Christopher M. Evans, Ting Xie, Felix Alonso-Valenteen, Lali K. Medina-Kauwe, Dianhua Jiang, Paul W. Noble, Cory M. Hogaboam, Nan Deng, Olivier Burgy, Travis J. Antes, Melanie Königshoff, Barry R. Stripp, Sina A. Gharib, Peter Chen

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Figure 4

EVs within fibrotic lungs have profibrotic properties.

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EVs within fibrotic lungs have profibrotic properties. (A–C) WT mice wer...
(AC) WT mice were injured with low-dose bleomycin (0.25 units/kg) and then given the respective treatments as indicated. Representative images of (A) H&E staining and (B) Picrosirius red staining (scale bar: 200 μm) on day 21 after bleomycin. Original magnification ×20. (C) Hydroxyproline content (n = 6–8 in each group) in the lungs after bleomycin treatment. *P < 0.05; **P < 0.005; ***P < 0.0005 by 1-way ANOVA analysis. (D and E) Mouse lung epithelial (MLE-12) cells were treated with control and fibrotic EVs and processed for RNA-Seq. (D) Heatmap of differentially expressed genes in MLE-12 cells treated with fibrotic EVs compared with control. (E) Profibrotic pathways identified by KEGG pathway analysis of upregulated MLE-12 cells in fibrotic EV–treated condition compared with control. Bars indicate the number of genes in the pathway and color indicates FDR level. Refer to Supplemental Table 2 for the entire gene list and KEGG pathway analysis.