平衡
细胞生物学
生物
椎间盘
神经科学
信号转导
能量稳态
椎间盘
再生(生物学)
解剖
作者
Jian He,Sha Huang,Yanfang Li,Yingbo Wang,P Yan,Ou Hu,Peng Lin,He Jin,Jun Zhu,Liang Zhang,Yaoyao Liu,Qin Qin,Yong Guo,Xiuhui Zheng,Yangli Xie,Le Chen,Yu Lan,Bing Liu,Peng Liu,Yibo Gan
出处
期刊:Cell Reports
[Cell Press]
日期:2026-03-01
卷期号:45 (3): 117076-117076
标识
DOI:10.1016/j.celrep.2026.117076
摘要
Intervertebral discs underpin spinal flexibility and stability during locomotion, yet the mechanism guiding their mechanoadaptive development remains inadequately elucidated. Here, we discovered a murine disc type programming spontaneous collagen deposition (collagenesis) within coccygeal regions under heightened mechanical loading, commencing around the 14th day after birth. In contrast to typical discs, these collagen-II-enriched discs (designated as type C) impart resistance to compressive and flexural stresses and lower susceptibility to degeneration. Their development involves a shift featuring emergent chondrogenic cell clusters independent of notochordal lineage and diminished notochord cells. Mechanistically, mechanical unloading inhibited type C disc formation, confirming collagenesis as a mechanoadaptive response. TRPV4 was highly expressed, and its deletion impaired collagenesis, underscoring the critical role of mechanotransduction. Critically, analogous mechanoadaptation programs in developing human lumbar spines demonstrate evolutionary conservation. Our findings reveal a fundamental collagenesis orchestrating mechanoadaptive disc development and lifelong homeostasis, offering insights into spinal function and relevant therapeutic strategies.
科研通智能强力驱动
Strongly Powered by AbleSci AI