成纤维细胞
巨噬细胞
主动脉夹层
下调和上调
细胞生物学
转录组
基因敲除
收缩性
受体
解剖(医学)
医学
血管平滑肌
表型
生物
重编程
解剖
细胞迁移
病理
体外
心脏病学
化学
主动脉
内科学
细胞
主动脉修补术
纤维化
肌球蛋白
斑马鱼
生物信息学
作者
Jing Tao,Huanjie Yang,Jiahui Yong,X Chen,Qiang Zhao,Xueli Wu,Lei Yan,Li Pang,Fan Luo,Mengjun Yu,Shanshan Pan,Deyang Li,R Y Chen,Yì Wáng,Zhensheng Dong,Fan Yang,Yue Wang,Yang Chen,Hongjian Zheng,Zhimin Yang
摘要
ABSTRACT Although single‐cell studies have profiled diseased aorta, mechanisms driving aortic dissection (AD) remain largely elusive owing to limited cohorts. Here, we integrate single‐cell and spatial transcriptomic data from 110 thoracic aortic samples (80 individuals; control, aneurysm, dissection; 767 018 high‐quality cells) to generate a comprehensive thoracic‐aorta cellular—molecular atlas. We identify an elastin‐rich fibroblast subset (Fibro_C1_FBN1+; FBN1 , MFAP5 , LOX ) that declines with age and is markedly depleted in AD, linking fibroblast loss to increased aortic wall vulnerability and dissection risk. Vascular smooth muscle cells (vSMCs) undergo ENO1 ‐driven glycolytic reprogramming under hypoxia, lose contractility and adopt a synthetic, MIF ‐secreting phenotype that engages macrophage receptors to promote macrophage recruitment and pro‐inflammatory polarization, leading aggregated macrophages to upregulate proteolytic and fibrinolytic pathways and thereby accelerate extracellular‐matrix degradation. In vitro and in vivo, ENO1 knockdown inhibits vSMC switching, reduces macrophage inflammation, and slows AD progression. This stromal‐immune axis suggests potential therapeutic targets in AD.
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