Liver Matrix Stiffening Modulates Tumor-Associated Hepatocyte Polyploid Homeostasis via Piezo1/RUNX2/Anillin Mechanosensitive Axis
Xinyi Luo, Yifan Zhang, Yiquan Lu, Nan Wang, Fengjie Hao, Yongjun Chen, Xiaochun Fei, Junqing Wang
Journal:INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES
IF:5.6
DOI:10.3390/ijms27114685
PMID:42278217
Published:2026-05-22
research field:癌症生物学分子肿瘤学肝脏病学信号转导细胞力学
Abstract
The human liver is a polyploid organ, dominantly featured by a high proportion of binuclear polyploid hepatocytes. Our recent study demonstrates that decline of the abundance of binuclear hepatocytes (ABH) plays a critical role in contributing to Hepatocellular carcinoma (HCC) formation, involving the cytokinesis regulator Anillin. However, the relevance between liver stiffness and the acquired ABH attenuation remains unclear. In this study, we set a mechanical environment gel with different gradients to simulate different liver stiffness environments, combined with the paired paracancerous liver tissues from real-world patients with HCC who underwent radical surgery. A mechanosensitive Piezo1/RUNX2/Anillin axis was discovered. As observed, the decline of ABH in paracancerous liver tissues is a noteworthy measurable value for tumor formation, correlated with the extent of liver matrix stiffness and dismal phenotypes. A stiffened culture environment may promote quick polyploid attenuation of hepatocytes, accompanied by high expression of Piezo1, a critical mechanosensitive ion channel, and a consequential nuclear translocation of RUNX2. Importantly, RUNX2 functions as an upstream transcription factor of Anillin. Regulating Piezo1/RUNX2 or using Piezo1 agonist remarkably affected Anillin expression and hepatocyte polyploidy homeostasis. Thus, we propose that the Piezo1/RUNX2/Anillin axis transduces the microenvironment mechanical signal from liver stiffening and impairs hepatocyte polyploidy homeostasis in HCC formation.
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