da Silva Junior Carlos Aparecido, Picardo Maria Cristina D, Del Negro Christopher A
Department of Applied Science, School of Computing, Data Sciences & Physics, William & Mary, Williamsburg, VA 23185, USA; Department of Biology, University of North Carolina at Greensboro, Greensboro, NC 2712, USA.
Department of Applied Science, School of Computing, Data Sciences & Physics, William & Mary, Williamsburg, VA 23185, USA.
Neuron. 2025 Jul 21. doi: 10.1016/j.neuron.2025.06.011.
Breathing movements depend on rhythmic neural activity in brainstem nuclei whose constituent neurons are well characterized. Knowing the sites and cells underlying the behavior enables us to identify the roles of individual ion channels. They accomplish three tasks: regulate excitability via the balance of intrinsic currents that govern baseline membrane potential and tonic firing; generate bursts to drive the motor output pattern; and transduce blood-gas levels, lung volume, and air qualities. Here, we explain how sodium and mixed cation channels (sodium leak channel non-selective [NALCN], Na1.6, and transient receptor potential [TRP] melastatin 4 [TRPM4]) both regulate excitability and generate bursts and how potassium (predominantly two-pore domain acid-sensitive potassium [TASK]-2) and mixed cation (PIEZO and TRP) channels encode sensory feedback to central control circuits. These mechanisms underlie normal breathing and sigh breaths. Breathing is a mammalian behavior in which rhythmogenesis and sensorimotor integration can be understood at multiple levels of analysis from microcircuits and cells to ion channels and genes.
呼吸运动依赖于脑干核团中的节律性神经活动,其组成神经元已得到充分表征。了解该行为背后的位点和细胞,有助于我们确定单个离子通道的作用。它们完成三项任务:通过控制基线膜电位和紧张性放电的内在电流平衡来调节兴奋性;产生爆发式放电以驱动运动输出模式;以及传导血气水平、肺容积和空气质量信息。在此,我们解释钠通道和混合阳离子通道(非选择性钠漏通道[NALCN]、Na1.6和瞬时受体电位[TRP]褪黑素4[TRPM4])如何调节兴奋性并产生爆发式放电,以及钾通道(主要是双孔结构域酸敏感钾通道[TASK]-2)和混合阳离子通道(压电通道和TRP通道)如何将感觉反馈编码至中枢控制回路。这些机制构成了正常呼吸和叹息呼吸的基础。呼吸是一种哺乳动物行为,在从微电路和细胞到离子通道和基因的多个分析层面上,都可以理解其节律产生和感觉运动整合过程。