Zhang Lu, Liu Yun-Feng, Luo Mi, Song Xue, Zhang Xin-Yuan, Sun Jing-Xian, Zhang Jian-Fei, Yuan Xiao-Ying, Chi Yan-Yan, Zhang Ruo-Tong, Li Chan, Gilmore Campbell, Yu Sheng-Bo, Ma Wei, Sui Hong-Jin
Department of Anatomy, College of Basic Medicine, Dalian Medical University, Dalian, China.
Department of Anatomy, College of Basic Medicine, Jilin Medical University, Jilin, China.
PLoS One. 2025 Aug 4;20(8):e0329754. doi: 10.1371/journal.pone.0329754. eCollection 2025.
The myodural bridge (MDB) represents specialized fibrous structures establishing connectivity between suboccipital musculature and the spinal dura mater (SDM). The suboccipital muscles, ligaments, and myodural bridge fibers together form a functional unit known as the myodural bridge complex (MDBC). Mechanical stress from suboccipital muscles may contribute to MDB maturation. Integrin α7 (ITGA7) is critical for skeletal muscle attachment to connective tissues, and is involved in the transmission of lateral and longitudinal forces in skeletal muscle. Given the muscle force transmission characteristics of ITGA7 and the dependence of MDB development on force transmission, we hypothesized that ITGA7 serves as a crucial link between RCDmi and the MDB it emits, and may involve in the development of MDBC. To test this, neonatal Sprague-Dawley (SD) rats were randomly allocated to shRNA-ITGA7, shRNA-NC control, lentiviral vectors were injected into the dorsal atlanto-occipital interspace. ITGA7 suppression significantly impaired MDB development and maturation, manifesting as disrupted fiber assembly and RCDmi muscle dystrophy. Ultrastructural analysis revealed disorganized collagen fiber architecture and an abundance of fibroblasts, indicative of immature collagen fibers, further corroborated by Picrosirius red staining. Additionally, ITGA7 knockdown resulted in diminished RCDmi muscle force and altered ECM-related gene expression profiles. A key finding of our study is the importance of ITGA7 as a direct molecular link between suboccipital muscles and MDB, suggesting that mechanical forces from suboccipital musculature fundamentally influence MDB differentiation and maturation. These findings substantiate MDB's role in force transmission to the SDM and by extension, advance our understanding of the molecular mechanisms underlying MDB development and its physiological significance.
肌硬膜桥(MDB)是一种特殊的纤维结构,在枕下肌肉组织与硬脊膜(SDM)之间建立连接。枕下肌肉、韧带和肌硬膜桥纤维共同构成一个功能单元,称为肌硬膜桥复合体(MDBC)。枕下肌肉产生的机械应力可能有助于MDB的成熟。整合素α7(ITGA7)对于骨骼肌附着于结缔组织至关重要,并参与骨骼肌横向和纵向力的传递。鉴于ITGA7的肌肉力传递特性以及MDB发育对力传递的依赖性,我们推测ITGA7是RCDmi与其发出的MDB之间的关键联系,并且可能参与MDBC的发育。为了验证这一点,将新生Sprague-Dawley(SD)大鼠随机分为shRNA-ITGA7组、shRNA-NC对照组,将慢病毒载体注射到寰枕背侧间隙。ITGA7抑制显著损害了MDB的发育和成熟,表现为纤维组装紊乱和RCDmi肌肉营养不良。超微结构分析显示胶原纤维结构紊乱,有成纤维细胞大量存在,表明胶原纤维不成熟,天狼星红染色进一步证实了这一点。此外,ITGA7敲低导致RCDmi肌肉力量减弱,并改变了与细胞外基质相关的基因表达谱。我们研究的一个关键发现是ITGA7作为枕下肌肉与MDB之间直接分子联系的重要性,这表明枕下肌肉组织产生的机械力从根本上影响MDB的分化和成熟。这些发现证实了MDB在向SDM传递力方面的作用,进而推进了我们对MDB发育的分子机制及其生理意义的理解。
