Increased expression and accumulation of GDF15 in IPF extracellular matrix contribute to fibrosis
Agata Radwanska, Christopher Travis Cottage, Antonio Piras, Catherine Overed-Sayer, Carina Sihlbom, Ramachandramouli Budida, Catherine Wrench, Jane Connor, Susan Monkley, Petra Hazon, Holger Schluter, Matthew J. Thomas, Cory M. Hogaboam, Lynne A. Murray
Agata Radwanska, Christopher Travis Cottage, Antonio Piras, Catherine Overed-Sayer, Carina Sihlbom, Ramachandramouli Budida, Catherine Wrench, Jane Connor, Susan Monkley, Petra Hazon, Holger Schluter, Matthew J. Thomas, Cory M. Hogaboam, Lynne A. Murray
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Research Article Cell biology Pulmonology

Increased expression and accumulation of GDF15 in IPF extracellular matrix contribute to fibrosis

Abstract

Idiopathic pulmonary fibrosis (IPF) is a chronic disease of unmet medical need. It is characterized by formation of scar tissue leading to a progressive and irreversible decline in lung function. IPF is associated with repeated injury, which may alter the composition of the extracellular matrix (ECM). Here, we demonstrate that IPF patient–derived pulmonary ECM drives profibrotic response in normal human lung fibroblasts (NHLF) in a 3D spheroid assay. Next, we reveal distinct alterations in composition of the diseased ECM, identifying potentially novel associations with IPF. Growth differentiation factor 15 (GDF15) was identified among the most significantly upregulated proteins in the IPF lung–derived ECM. In vivo, GDF15 neutralization in a bleomycin-induced lung fibrosis model led to significantly less fibrosis. In vitro, recombinant GDF15 (rGDF15) stimulated α smooth muscle actin (αSMA) expression in NHLF, and this was mediated by the activin receptor-like kinase 5 (ALK5) receptor. Furthermore, in the presence of rGDF15, the migration of NHLF in collagen gel was reduced. In addition, we observed a cell type–dependent effect of GDF15 on the expression of cell senescence markers. Our data suggest that GDF15 mediates lung fibrosis through fibroblast activation and differentiation, implicating a potential direct role of this matrix-associated cytokine in promoting aberrant cell responses in disease.

Authors

Agata Radwanska, Christopher Travis Cottage, Antonio Piras, Catherine Overed-Sayer, Carina Sihlbom, Ramachandramouli Budida, Catherine Wrench, Jane Connor, Susan Monkley, Petra Hazon, Holger Schluter, Matthew J. Thomas, Cory M. Hogaboam, Lynne A. Murray

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Figure 1

Diseased lung ECM promotes fibroblast-to-myofibroblast transition.

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Diseased lung ECM promotes fibroblast-to-myofibroblast transition. (A an...
(A and B) Decellularized and weight-normalized ECM from healthy or IPF lung (n = 8 donors) was cocultured with NHLF using 3D spheroid hanging drop system, and αSMA and nuclei were immunofluorescence labeled. Image analysis–based αSMA quantification was performed using ImageXpress Micro system, and the percentage of αSMA+ cells was calculated in each spheroid (>14 spheroids per patient) using MetaXpress High Content Image Analysis Software at day 4 (A) and day 8 (B) of culture. The data are presented as mean ± SD, with dots representing single patients, and they were statistically analyzed with 2-tailed Mann Whitney U test in comparison with healthy subjects; *P < 0.05 and ****P < 0.0001. (C) Representative immunofluorescence staining (5 experiments conducted) of αSMA (red) and nuclei (blue) in 3D spheroids, day 8. Magnified area is marked with dotted line. Scale bar: 100 μm. (D) PCA plot representing the data from proteomic analysis of decellularized ECM derived from healthy lung (blue; n = 7 donors) and IPF lung (pink; n = 7 donors). (E) IPA analysis of the top 10 significantly (–log[P value] > 1.30) enriched canonical pathways based on differentially expressed proteins in IPF ECM compared with healthy ECM. The data are presented as IPA –log(P value), and the ratio of proteins is represented in each pathway. (F) Heatmap comparison of significantly altered proteins (FC > 2.8 and FC < 0.36, q < 0.05, statistically analyzed with unpaired Student’s t test), identified in the proteome of IPF (pink) and healthy (blue) ECM from patient lung-derived samples. (G) The top-ranked proteins identified in IPF ECM plotted based on abundance and compared with healthy ECM. The data are expressed as log2FC. (H and I) Box-and-whisker plots representing FC over internal control (ref) for TGF-β1 (H) and GDF15 (I) identified in the proteome of healthy and IPF lung ECM (n = 7, dots represent single patients). Statistically analyzed with Mann Whitney U test; ***P < 0.001.