肌成纤维细胞
自噬
平滑
肾
纤维化
细胞生物学
癌症研究
化学
信号转导
机制(生物学)
医学
心脏纤维化
肾脏疾病
生物
成纤维细胞生长因子
成纤维细胞
肾小管
肾小球硬化
转化生长因子
抑制器
作者
Xiaonan Wang,Ye Liang,Jiemei Li,Xiaoxu Wang,Weijie Zhong,Yabing Xiong,Wenting Ye,Canzhen Liu,Xian Ling,Jinhua Miao,Weiwei Shen,Shan Zhou,Ping Meng,Youhua Liu,Fan Fan Hou,Xiaolong Li,Lili Zhou
标识
DOI:10.1016/j.kint.2026.01.028
摘要
INTRODUCTION: Kidney fibrosis progressively induces kidney function loss, leading to kidney failure. Myofibroblast transition from fibroblast is significantly involved in the development of kidney fibrosis. Previous studies revealed that sonic hedgehog (Shh), the upstream ligand of Smoothened (Smo) receptor signaling, contributes to kidney fibrosis. However, the role of Smo in fibroblast activation remains unclear. METHODS: Here, fibroblast-specific Smo and β-catenin knockout mice were generated, primary kidney fibroblasts were isolated and cultured. Single-nucleus (snRNA-seq) plus bulk RNA sequencing were performed. Autophagy capacities, including autophagy flux, autophagy vacuoles, and autophagy-related gene expression, were assessed. RESULTS: From snRNA-seq data of the human atlas combined with bulk RNA sequencing of primary mouse kidney fibroblasts, we discovered Smo was upregulated in kidney fibroblasts in chronic kidney disease (ureteral obstruction, ischemia/reperfusion, Adriamycin nephrosis and 5/6th nephrectomy models). This was accompanied by substantially diminished autophagic capacity. Shh stimulation or ectopic Smo deactivated autophagy, exaggerated myofibroblast proliferation and activation in the fibroblasts. These effects were further enhanced in autophagosome protein ATG5 knockout fibroblasts. Moreover, Smo, through the β-arrestin 1/Src/β-catenin pathway, induced the transcription of mammalian target of rapamycin. This mediated autophagy suppression in fibroblasts, leading to myofibroblast activation and kidney fibrosis. Fibroblast-specific knockout of Smo or β-catenin greatly preserves autophagy capacity and ameliorates kidney fibrosis. Notably, NVP-LDE225, a specific Smo antagonist, effectively restored fibroblast autophagy and retarded kidney fibrotic lesion formation. CONCLUSIONS: Our study defines a prominent mechanism of myofibroblast activation and supplies a potential avenue for targeting fibroblast Smo to treat chronic kidney disease.
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