伤口愈合
收缩性
蛋白质水解
成纤维细胞
细胞生物学
肺
组织重塑
化学
医学
炎症
生物
内科学
免疫学
生物化学
体外
酶
作者
Hugh Xiao,K. S. B. Sylla,Xiangyu Gong,Brendan Wilkowski,Alejandro Rossello‐Martinez,Seyma Nayir Jordan,Emmanuel Y. Mintah,Allen Zheng,Huanxing Sun,Erica L. Herzog,Michael Mak
标识
DOI:10.1002/adhm.202400941
摘要
Damage and repair are recurring processes in tissues, with fibroblasts playing key roles by remodeling extracellular matrices (ECM) through protein synthesis, proteolysis, and cell contractility. Dysregulation of fibroblasts can lead to fibrosis and tissue damage, as seen in idiopathic pulmonary fibrosis (IPF). In advanced IPF, tissue damage manifests as honeycombing, or voids in the lungs. This study explores how transforming growth factor-beta (TGF-β), a crucial factor in IPF, induces lung fibroblast spheroids to create voids in reconstituted collagen through proteolysis and cell contractility, a process we termed as hole formation. These voids reduce when proteases are blocked. Spheroids mimic fibroblast foci observed in IPF. Results indicate that cell contractility mediates tissue opening by stretching fractures in the collagen meshwork. Matrix metalloproteinases (MMPs), including MMP1 and MT1-MMP, are essential for hole formation, with invadopodia playing a significant role. Blocking MMPs reduces hole size and promotes wound healing. This study shows how TGF-β induces excessive tissue destruction and how blocking proteolysis can reverse damage, offering insights into IPF pathology and potential therapeutic interventions.
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