Remodeled Extracellular Matrix Guides Endothelial Cell Phenotype and Transcriptome to Fibrotic Niche

Impairment of endothelial barrier integrity causes vascular injury leading to acute lung injury (ALI), which, if not resolved, can compromise a patient’s lung functions and mortality. While it is known that both endothelial cells (EC) and their underlying extracellular matrix (ECM) are required for preserving lung homeostasis and functions, much of the efforts to understand mechanisms regulating these functions have focused mainly on EC. A fundamental unresolved question is whether lung-remodeled ECM formed due to leaky endothelium impacts EC functions, and if so, how? Herein, using lung ECM derived from a mouse lacking focal adhesion kinase (FAK), specifically in the endothelium (remodeled ECM), we assessed ECM components and their role in regulating EC functions and their relevance in vivo. Previously, we have shown that conditional deletion of FAK in endothelium increases EC permeability and induces vascular injury at homeostasis. Mass spectrometric analysis showed 805 proteins in control ECM (FAKfl/fl mice lung derived ECM) consisting of glycoproteins, matrisome-associated proteins, and secreted factors. However, the remodeled ECM had 722 proteins and was highly enriched with fibrillin 1, fibrinogen, and collagen I. Moreover, the remodeled ECM was two-fold stiffer than the control ECM. Remodeled ECM with its inherent composition recapitulates the 3D microenvironment, encouraging EC morphological alteration, increased cell stiffness, and enhanced focal adhesion (FA) formation compared to control ECM. In addition, RNA sequencing identified increased expression of genes linked with fibrosis, including integrin b8, TGFb2, GDF15, SMAD7, COL1A1, IL33, ID3, BMPR1A, and ADAMTS4 in EC seeded on remodeled ECM. Interestingly, fibrotic signaling observed in EC plated on remodeled ECM mimicked in vivo in EC-FAK−/− mice as they showed increased hydroxyproline content and collagen deposition in the lungs, indicating loss of EC-FAK as the crucial initiator of fibrotic signaling. In summary, studies for the first time show disrupted EC signaling as the instructor of fibrotic niche in the lungs for targeting pulmonary fibrosis. NIH. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.