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Endothelial GDF15 deficiency enhances barrier function and mitigates pulmonary fibrosis
Kristen Raffensperger, Marta Bueno, Brian J. Philips, Megan Miller, Máté Katona, Shuai Yuan, Adriana Estrada-Bernal, Byron Chuan, Pavan Suresh, Stephanie Taiclet, Scott Hahn, Yingze Zhang, Jonathan K. Alder, Seyed Mehdi Nouraie, Daniel J. Kass, Oliver Eickelberg, Adam C. Straub
Kristen Raffensperger, Marta Bueno, Brian J. Philips, Megan Miller, Máté Katona, Shuai Yuan, Adriana Estrada-Bernal, Byron Chuan, Pavan Suresh, Stephanie Taiclet, Scott Hahn, Yingze Zhang, Jonathan K. Alder, Seyed Mehdi Nouraie, Daniel J. Kass, Oliver Eickelberg, Adam C. Straub
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Research Article Cell biology Pulmonology Vascular biology

Endothelial GDF15 deficiency enhances barrier function and mitigates pulmonary fibrosis

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Abstract

Pulmonary fibrosis is frequently accompanied by pulmonary hypertension, which can occur disproportionate to the extent of fibrosis, suggesting a fibrosis-independent vascular remodeling process. Here, we demonstrated that plasma growth differentiation factor 15 (GDF15) is elevated across diverse fibrotic lung disease subtypes and correlates with markers of elevated right heart pressures but not pulmonary function indices, indicating a possible link to endothelial cell dysfunction. To investigate the import of endothelial GDF15 as a modifier of lung fibrosis pathogenesis, we generated endothelial cell–specific Gdf15-KO mice, which showed protection from bleomycin-induced lung injury and fibrosis, with preserved lung function. RNA-seq of human pulmonary microvascular endothelial cells revealed altered expression of barrier-regulatory genes in GDF15-deficient endothelial cells compared with controls. Functional studies confirmed that GDF15 knockdown attenuates thrombin-induced barrier disruption by reducing cytosolic Ca2+ responses. Together, these findings implicate endothelial GDF15 as a modifier of vascular permeability and Ca2+ signaling and a contributor to lung injury and fibrosis.

Authors

Kristen Raffensperger, Marta Bueno, Brian J. Philips, Megan Miller, Máté Katona, Shuai Yuan, Adriana Estrada-Bernal, Byron Chuan, Pavan Suresh, Stephanie Taiclet, Scott Hahn, Yingze Zhang, Jonathan K. Alder, Seyed Mehdi Nouraie, Daniel J. Kass, Oliver Eickelberg, Adam C. Straub

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Figure 4

RNA-seq reveals upregulation of junctional proteins with GDF15 knockdown.

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RNA-seq reveals upregulation of junctional proteins with GDF15 knockdown...
(A) Based on the log-transformed count per million reads (CPM) values, we selected the top 1,000 genes with the highest variance, which were used for principal component analysis. The samples are shown as dots according to their positions on the first 2 principal components (PC1/PC2). The samples are colored by their groups. (B) The volcano plot shows how gene expression is altered by GDF15 silencing. Genes are shown as dots based on their log2 fold change (log2FC) and –log10FDR comparing siGDF15 to siNT. Significant genes (FDR < 0.05) are colored in red (upregulated) or blue (downregulated). (C) The top 10 enrichment Gene Ontology biological processes, ranked by their FDR, are shown as density plots. The height of the density plot indicates the number of genes with the indicated log2 fold change (log2FC). Individual genes are shown as bars under the density plot. The color of the density plot represents the fold enrichment in the over-representation test. (D) Significant pathways of interest (P < 0.05) are selected. The most significant genes (FDR < 10–4) involved in these pathways are linked to the pathways in a chord plot. The genes are ranked in descending order based on log2FC (siGDF15 over siNT), which is indicated by the color bar next to the gene name.

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ISSN 2379-3708

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