Cell–cell coupling in CO2/H+-excited neurons in brainstem slices

Respiration physiology Pub Date : 2001-12-01 DOI:10.1016/S0034-5687(01)00284-5

Jay B Dean, Elizabeth A Kinkade, Robert W Putnam

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引用次数: 70

Abstract

The indirect and direct electrical and anatomical evidence for the hypothesis that central chemoreceptor neurons in the dorsal brainstem (solitary complex, SC; locus coeruleus, LC) are coupled by gap junctions, as reported primarily in rat brainstem slices, and the methods used to study gap junctions in brain slices, are critiqued and reviewed. Gap junctions allow intercellular communication that could be important in either electrical coupling (intercellular flow of ionic current), metabolic coupling (intercellular flow of signaling molecules), or both, ultimately influencing excitability within the SC and LC during respiratory acidosis. Gap junctions may also provide a mechanism for modulating neuronal activity in the network under conditions that lead to increased or decreased central respiratory chemosensitivity. Indirect measures of electrical coupling suggest that junctional conductance between chemosensitive neurons is relatively insensitive to a broad range of intracellular pH (pH_i), ranging from pH_i ≈7.49 to ≈6.71 at 35–37 °C. In contrast, further reductions in pH_i, down through pH_i ≈6.67, abolish indirect measures of electrical coupling.

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脑干切片中CO2/H+兴奋神经元的细胞-细胞耦合

脑干背侧中枢化学感受器神经元(孤立复合体，SC;蓝斑座(locus bluuleus, LC)主要在大鼠脑干切片中与间隙连接偶联，本文对研究脑切片中间隙连接的方法进行了批评和回顾。间隙连接允许细胞间通信，这可能在电偶联(离子电流的细胞间流动)、代谢偶联(信号分子的细胞间流动)或两者中都很重要，最终影响呼吸性酸中毒期间SC和LC内的兴奋性。间隙连接也可能提供一种机制，在导致中枢呼吸化学敏感性增加或降低的条件下调节网络中的神经元活动。电偶联的间接测量表明，化学敏感神经元之间的结电导对细胞内pH (pHi)的范围相对不敏感，在35-37°C时，pH≈7.49至≈6.71。相反，进一步降低pHi，直到pHi≈6.67，取消了电耦合的间接措施。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Respiration physiology

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