A model of tight junction function in central nervous system myelinated axons.

Alexander Gow, Jerome Devaux
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引用次数: 29

Abstract

The insulative properties of myelin sheaths in the central and peripheral nervous systems (CNS and PNS) are widely thought to derive from the high resistance and low capacitance of the constituent membranes. Although this view adequately accounts for myelin function in large diameter fibers, it poorly reflects the behavior of small fibers that are prominent in many regions of the CNS. Herein, we develop a computational model to more accurately represent conduction in small fibers. By incorporating structural features that, hitherto, have not been simulated, we demonstrate that myelin tight junctions (TJs) improve saltatory conduction by reducing current flow through the myelin, limiting axonal membrane depolarization and restraining the activation of ion channels beneath the myelin sheath. Accordingly, our simulations provide a novel view of myelin by which TJs minimize charging of the membrane capacitance and lower the membrane time constant to improve the speed and accuracy of transmission in small diameter fibers. This study establishes possible mechanisms whereby TJs affect conduction in the absence of overt perturbations to myelin architecture and may in part explain the tremor and gait abnormalities observed in Claudin 11-null mice.

中枢神经系统髓系轴突紧密连接功能模型。
髓鞘在中枢和外周神经系统(CNS和PNS)中的绝缘特性被广泛认为是由于其组成膜的高电阻和低电容。尽管这一观点充分解释了髓磷脂在大直径纤维中的功能,但它不能很好地反映在中枢神经系统许多区域中突出的小纤维的行为。在此,我们开发了一个计算模型来更准确地表示小纤维中的传导。通过整合迄今尚未模拟的结构特征,我们证明髓鞘紧密连接(TJs)通过减少通过髓鞘的电流、限制轴突膜去极化和抑制髓鞘下离子通道的激活来改善跳跃传导。因此,我们的模拟为髓磷脂提供了一个新的视角,通过TJs最小化膜电容的充电,降低膜时间常数,以提高在小直径光纤中的传输速度和准确性。本研究建立了TJs在髓鞘结构没有明显扰动的情况下影响传导的可能机制,并可能部分解释在Claudin 11-null小鼠中观察到的震颤和步态异常。
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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来源期刊
Neuron glia biology
Neuron glia biology 医学-神经科学
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