Differential roles of Na_V1.2 and Na_V1.6 in neocortical pyramidal cell excitability.

IF 6.4 1区生物学 Q1 BIOLOGY

eLife Pub Date : 2025-07-15 DOI:10.7554/eLife.105696

Joshua D Garcia, Chenyu Wang, Ryan P D Alexander, Emmie Banks, Timothy Fenton, Jean-Marc DeKeyser, Tatiana V Abramova, Alfred L George, Roy Ben-Shalom, David H Hackos, Kevin J Bender

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引用次数: 0

Abstract

Mature neocortical pyramidal cells functionally express two sodium channel (Na_V) isoforms: Na_V1.2 and Na_V1.6. These isoforms are differentially localized to pyramidal cell compartments, and as such are thought to contribute to different aspects of neuronal excitability. But determining their precise roles in pyramidal cell excitability has been hampered by a lack of tools that allow for selective, acute block of each isoform individually. Here, we leveraged aryl sulfonamide-based molecule (ASC) inhibitors of Na_V channels that exhibit state-dependent block of both Na_V1.2 and Na_V1.6, along with knock-in mice with changes in Na_V1.2 or Na_V1.6 structure that prevents ASC binding. This allowed for acute, potent, and reversible block of individual isoforms that permitted dissection of the unique contributions of Na_V1.2 and Na_V1.6 in pyramidal cell excitability. Remarkably, block of each isoform had contrasting-and in some situations, opposing-effects on neuronal action potential output, with Na_V1.6 block decreasing and Na_V1.2 block increasing output. Thus, Na_V isoforms have unique roles in regulating different aspects of pyramidal cell excitability, and our work may help guide the development of therapeutics designed to temper hyperexcitability through selective Na_V isoform blockade.

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NaV1.2和NaV1.6在新皮质锥体细胞兴奋性中的差异作用。

成熟的新皮质锥体细胞在功能上表达两种钠通道（NaV）异构体：NaV1.2和NaV1.6。这些同工异构体不同地定位于锥体细胞区室，因此被认为对神经元兴奋性的不同方面有贡献。但是确定它们在锥体细胞兴奋性中的精确作用一直受到缺乏工具的阻碍，因为缺乏工具可以选择性地、急性地单独阻断每种同工异构体。在这里，我们利用了基于芳基磺酰胺的NaV通道抑制剂（ASC），其表现出NaV1.2和NaV1.6的状态依赖性阻断，以及NaV1.2或NaV1.6结构变化阻止ASC结合的敲入小鼠。这使得单个同工异构体的急性、有效和可逆阻断成为可能，从而允许对锥体细胞兴奋性中NaV1.2和NaV1.6的独特贡献进行解剖。值得注意的是，每个同工异构体的阻断对神经元动作电位输出的影响是相反的，在某些情况下是相反的，NaV1.6阻断减少，NaV1.2阻断增加。因此，NaV异构体在调节锥体细胞兴奋性的不同方面具有独特的作用，我们的工作可能有助于指导通过选择性阻断NaV异构体来调节过度兴奋性的治疗方法的发展。

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

eLife BIOLOGY-

CiteScore

12.90

自引率

3.90%

发文量

3122

审稿时长

17 weeks

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