医学
肌腱病
伤害感受器
神经突
神经生长因子
背根神经节
神经科学
感觉系统
肌腱
降钙素基因相关肽
成纤维细胞生长因子
原肌球蛋白受体激酶A
三叉神经节
感觉神经
伤害
感觉神经元
神经损伤
细胞生物学
病理
解剖
信号灯
FGF1型
神经营养因子
腓肠神经
条件基因敲除
生物
神经系统
基因靶向
轴突
轴突切开术
神经瘤
神经可塑性
作者
Manyu Zhu,Xin Xing,Zhao Li,Beicheng Du,Mingxin Xu,Myles Zhou,Meng Shi,Qizhi Qin,Mary Archer,Chunbao Rao,Masnsen Cherief,Sowmya Ramesh,Neelima Thottappillil,Chase A. Pagani,Bandarigoda N. Somatilaka,Xu Cao,Benjamin Levi,Yun Guan,A. Everette James
标识
DOI:10.1126/scitranslmed.aec1380
摘要
Chronic tendinopathy is typified by persistent tendon-associated pain, transmitted by local nociceptive neurons. However, the regulatory function of somatosensory neurons in the development of tendinopathy is unknown. Here, we show that sensory neurons grow into the tendon proper across preclinical models of chronic tendinopathy to serve a protective function against tendinopathic changes through interactions with resident tenocytes and infiltrating macrophages. Retrograde neuronal tracing combined with single-cell RNA sequencing (scRNA-seq) of dorsal root ganglion neurons revealed a tendon-specific innervation profile, including calcitonin gene–related peptide (CGRP)–positive nociceptors among other sensory neuron types. We further evaluated these findings in three complementary surgical and transgenic mouse models of disrupted sensory nerve growth. Conditional deletion of nerve growth factor ( Ngf ) in macrophages ( Ngf Csfr1 ) or inactivation of its high-affinity receptor, tropomyosin receptor kinase A (TrkA), on sensory neurons exacerbated tendinopathic changes. Subsequently, a “sensory-only” sural nerve denervation model phenocopied these results, including heightened macrophage infiltration and tenocyte apoptosis. scRNA-seq of tendinous tissue identified defective tenocyte differentiation and altered macrophage migration and polarization with tendon denervation. Last, neuron-tendon interaction analyses implicated neuron-derived fibroblast growth factor 1 (FGF1) as a preventative factor for tendon degeneration, a finding supported by tendon organ culture and in vivo assessment. Consistent with a conserved mechanism, human tendinopathy specimens showed FGF1 immunoreactivity associated with tendon-innervating nerve fibers. Collectively, our findings demonstrate that peripheral afferent neural networks exert a protective effect in preclinical tendinopathy models by secreting FGF1 and that targeting this pathway may offer therapeutic strategies to prevent tendinopathic changes.
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