原发性纤毛介导的机械刺激对骨-肌腱愈合过程中巢蛋白阳性骨髓间充质干细胞的影响。
The effects of primary cilia-mediated mechanical stimulation on nestin-BMSCs during bone-tendon healing.
作者信息
Chen Huabin, Xiao Han, Wu Bing, Shi Xin, Guan Changbiao, Hu Jianzhong, Zhang Tao, Lu Hongbin
机构信息
Department of Sports Medicine, Xiangya Hospital, Central South University, Changsha, China; Department of Sports Medicine, Center for Orthopedic Surgery, The Third Affiliated Hospital of Southern Medical University, China; National Clinical Research Center for Geriatric Disorders, Xiangya Hospital, Central South University, Changsha, China.
Department of Sports Medicine, Xiangya Hospital, Central South University, Changsha, China; Key Laboratory of Organ Injury, Aging and Regenerative Medicine of Hunan Province, Changsha, China.
出版信息
J Adv Res. 2025 Aug;74:415-427. doi: 10.1016/j.jare.2024.09.012. Epub 2024 Sep 19.
INTRODUCTION
Mechanical stimulation has been proven to promote bone-tendon interface (BTI) healing, but the mechanism remains unclear.
OBJECTIVE
To investigate the effects of mechanical stimulation on the biological behavior of nestin-bone mesenchymal stem cells (BMSCs) during the BTI healing, and to reveal the mechanisms of mechanical stimulation affecting BTI healing by primary cilia on the nestin-BMSCs.
METHODS
Transgenic tracing mice (nestin cre:: IFT88/ROSA26 YFP) with primary cilia on nestin-BMSCs conditioned knocked out were constructed, and the littermates (nestin cre:: ROSA26 YFP) with normal cilia on nestin-BMSCs were the control. After establishing mouse supraspinatus insertion injury models, samples were collected at week-2 (n = 5 per group), 4 and 8 (n = 15 per group, respectively). In vivo, the repair efficiency was evaluated by histology, imaging, biomechanics, and the migration of nestin-BMSCs, detected by immunofluorescence staining. In vitro, nestin BMSCs were sorted and stimulated by tensile force to study the mechanisms of primary cilium-mediated mechanosensitive basis.
RESULTS
Mechanical stimulation (MS) accelerated the recruitment of nestin-BMSCs and promoted osteogenic and chondrogenic capacity. Histological, imaging and biomechanical results showed that the BTI healing quality of the IFT88, MS group was better than that of the other groups. After the conditionally knockout IFT88 in nestin-BMSCs, the repair ability of the BTI was obviously deteriorated, even though mechanical stimulation did not increase significantly (IFT88, MS group). In vitro results showed the tensile loading enhanced the proliferation, migration and osteogenic or chondrogenic gene expression of nestin-BMSCs with normal cilia. On the other hand, osteogenesis and chondrogenic expression were significantly decreased after inhibiting actin- Hippo/YAP pathway components.
CONCLUSION
The primary cilia mediated mechanical stimulation regulated osteogenic and chondrogenic differentiation potential of nestin-BMSCs through the actin- Hippo/YAP pathway, and then promoted the BTI healing process.
引言
机械刺激已被证明可促进骨-肌腱界面(BTI)愈合,但其机制尚不清楚。
目的
研究机械刺激对BTI愈合过程中巢蛋白阳性骨髓间充质干细胞(BMSCs)生物学行为的影响,并揭示机械刺激通过巢蛋白阳性BMSCs上的初级纤毛影响BTI愈合的机制。
方法
构建巢蛋白阳性BMSCs条件性敲除初级纤毛的转基因示踪小鼠(巢蛋白cre::IFT88/ROSA26 YFP),以巢蛋白阳性BMSCs上有正常纤毛的同窝小鼠(巢蛋白cre::ROSA26 YFP)作为对照。建立小鼠冈上肌止点损伤模型后,在第2周(每组n = 5)、第4周和第8周(每组分别n = 15)采集样本。在体内,通过组织学、影像学、生物力学评估修复效率,并通过免疫荧光染色检测巢蛋白阳性BMSCs的迁移情况。在体外,分选巢蛋白阳性BMSCs并施加拉伸力刺激,以研究初级纤毛介导的机械敏感基础机制。
结果
机械刺激(MS)加速了巢蛋白阳性BMSCs的募集,并促进了成骨和成软骨能力。组织学、影像学和生物力学结果表明,IFT88基因敲除+MS组的BTI愈合质量优于其他组。巢蛋白阳性BMSCs条件性敲除IFT88后,BTI的修复能力明显下降,即使机械刺激没有显著增加(IFT88基因敲除+MS组)。体外结果显示,拉伸加载增强了有正常纤毛的巢蛋白阳性BMSCs的增殖、迁移以及成骨或成软骨基因表达。另一方面,抑制肌动蛋白-Hippo/YAP信号通路成分后,成骨和成软骨表达显著降低。
结论
初级纤毛介导的机械刺激通过肌动蛋白-Hippo/YAP信号通路调节巢蛋白阳性BMSCs的成骨和成软骨分化潜能,进而促进BTI愈合过程。
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