祖细胞
脂肪细胞
细胞生物学
纤维化
祖细胞
转化生长因子
伤口愈合
生物
癌症研究
免疫学
医学
干细胞
病理
脂肪组织
内分泌学
作者
Meimei Yin,Lixiang Sun,Shuai Wu,Jinhang Ma,Wenlu Zhang,Xiaoxuan Ji,Zhichong Tang,Xiaowei Zhang,Yichun Yang,Xinyuan Zhang,Jinwen Huang,Shaoluan Zheng,Wenjie Liu,Chao Ji,Ling‐juan Zhang
摘要
Abstract Aberrant activation of dermal fibroblasts during wound healing often leads to debilitating fibrotic changes in the skin, such as scleroderma and keloids. However, the underlying cellular and molecular mechanisms remain elusive. Here, we established a wound‐induced skin fibrosis (WISF) mouse model in mature adult mice, characterised by excessive deposition of collagen bundles, loss of dermal adipocytes, and enrichment of DPP4 + Ly6A + THY1 + hypodermal interstitial adipocyte progenitors (HI‐APs) and pericytes, resembling human fibrotic skin diseases. This WISF model exhibited an age‐dependent gain of fibrotic characteristics, contrasting with the wound‐induced hair neogenesis observed in younger mice. Through comprehensive analyses of the WISF, we delineated a trajectory of fibroblast differentiation that originates from HI‐APs. These progenitors highly expressed several extracellular matrix (ECM) genes and exhibited a TGFβ pathway signature. TGFβ was identified as the key signal to inhibit the adipogenic potential and maintain the fibrogenic potential of dermal APs. Additionally, administering a TGFβ receptor inhibitor to wound scar reduced the abundance of ECM‐producing APs. Finally, analysis of human scleroderma skin tissues revealed a negative correlation between the expression of AP‐, ECM‐, and TGFβ pathway‐related genes and PPARG. Overall, this study establishes a wound‐induced skin fibrosis mouse model and demonstrates that TGFβ‐mediated blockage of HI‐AP differentiation is crucial for driving fibrotic pathology. Targeting HI‐APs and adipogenesis may provide novel avenues for developing disease‐modifying therapies for fibrotic skin diseases.
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