Liang Yanan, Luo Meiling, Xu Qianxi, Zhang Siqi, Niu Shuangyang, Li Xiaohe, Sun Weizhen, Song Menghan, Wang Likai, Xing Xiangxin, Wang Jie, Feng Mengqi, Zhao Linlin, Chen Handong, Sheng Run, Wang Yonghui
Rehabilitation Center, Qilu Hospital of Shandong University, Jinan, Shandong, China; University of Health and Rehabilitation Sciences, Qingdao, Shandong, China.
Rehabilitation Center, Qilu Hospital of Shandong University, Jinan, Shandong, China.
Br J Anaesth. 2025 Sep;135(3):710-722. doi: 10.1016/j.bja.2025.04.048. Epub 2025 Jul 23.
Microglia-neuronal communication is crucial for the development and maintenance of pain. However, the exact mechanisms underlying this interaction and its role in anterior cingulate cortex (ACC) circuitry in pain regulation are under exploration.
We explored the role of P2X4R-brain-derived neurotrophic factor (BDNF)-TrkB signalling of ACC in regulating muscle pain (MP). Mechanical and thermal pain thresholds along with open field tests were used to assess pain and anxiety-like behaviours. Golgi staining, transmission electron microscopy, and patch-clamp recordings were performed to evaluate synaptic plasticity changes. Meanwhile, cFos staining and calcium imaging substantiate the neuronal excitability. In addition, we used chemogenetic and optogenetic approaches to manipulate ACC neuronal activity.
The ACC exhibited increased excitability, together with enhanced synaptic plasticity in rats with chronic MP. Microglial inhibition alleviated pain and anxiety-like behaviours. Furthermore, microglial P2X4R promoted BDNF expression, which acted on TrkB to regulate neuronal excitability and synaptic plasticity in ACC; these effects were reversed by P2X4R knockdown and TrkB inhibition in MP. Chemogenetic and optogenetic suppression of ACC hyperactivity relieved chronic MP and anxiety-like behaviours.
Our findings highlight a critical microglia-neuronal communication via the P2X4R-BDNF-TrkB signalling, which enhances synaptic plasticity and cortical excitability in the anterior cingulate cortex, thereby participating in the regulation of muscle pain. Understanding how to assess and modulate microglia-neuronal communication and abnormal cortical activity will be key to developing novel therapies for MP disorders.
小胶质细胞与神经元的通讯对于疼痛的发生发展及维持至关重要。然而,这种相互作用的具体机制及其在疼痛调节中前扣带回皮质(ACC)神经回路中的作用仍在探索之中。
我们探究了ACC中P2X4R-脑源性神经营养因子(BDNF)-TrkB信号通路在调节肌肉疼痛(MP)中的作用。采用机械和热痛阈值以及旷场试验来评估疼痛和焦虑样行为。进行高尔基染色、透射电子显微镜检查和膜片钳记录以评估突触可塑性变化。同时,cFos染色和钙成像证实神经元兴奋性。此外,我们使用化学遗传学和光遗传学方法来操纵ACC神经元活动。
在慢性MP大鼠中,ACC兴奋性增加,同时突触可塑性增强。小胶质细胞抑制减轻了疼痛和焦虑样行为。此外,小胶质细胞P2X4R促进BDNF表达,BDNF作用于TrkB以调节ACC中的神经元兴奋性和突触可塑性;在MP中,P2X4R基因敲低和TrkB抑制可逆转这些作用。化学遗传学和光遗传学抑制ACC的过度活动可缓解慢性MP和焦虑样行为。
我们的研究结果突出了通过P2X4R-BDNF-TrkB信号通路进行的关键小胶质细胞与神经元通讯,该信号通路增强了前扣带回皮质的突触可塑性和皮质兴奋性,从而参与肌肉疼痛的调节。了解如何评估和调节小胶质细胞与神经元通讯以及异常的皮质活动将是开发针对MP疾病新疗法的关键。
