Diverse biophysical mechanisms in voltage-gated sodium channel Nav1.4 variants associated with myotonia

IF 4.4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

FASEB Journal Pub Date : 2024-08-16 DOI:10.1096/fj.202400867R

Tatiana B. Tikhonova, Artem A. Sharkov, Boris S. Zhorov, Alexander A. Vassilevski

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Abstract

Mutations in SCN4A gene encoding Na_v1.4 channel α-subunit, are known to cause neuromuscular disorders such as myotonia or paralysis. Here, we study the effect of two amino acid replacements, K1302Q and G1306E, in the DIII–IV loop of the channel, corresponding to mutations found in patients with myotonia. We combine clinical, electrophysiological, and molecular modeling data to provide a holistic picture of the molecular mechanisms operating in mutant channels and eventually leading to pathology. We analyze the existing clinical data for patients with the K1302Q substitution, which was reported for adults with or without myotonia phenotypes, and report two new unrelated patients with the G1306E substitution, who presented with severe neonatal episodic laryngospasm and childhood-onset myotonia. We provide a functional analysis of the mutant channels by expressing Na_v1.4 α-subunit in Xenopus oocytes in combination with β1 subunit and recording sodium currents using two-electrode voltage clamp. The K1302Q variant exhibits abnormal voltage dependence of steady-state fast inactivation, being the likely cause of pathology. K1302Q does not lead to decelerated fast inactivation, unlike several other myotonic mutations such as G1306E. For both mutants, we observe increased window currents corresponding to a larger population of channels available for activation. To elaborate the structural rationale for our experimental data, we explore the contacts involving K/Q1302 and E1306 in the AlphaFold2 model of wild-type Na_v1.4 and Monte Carlo-minimized models of mutant channels. Our data provide the missing evidence to support the classification of K1302Q variant as likely pathogenic and may be used by clinicians.

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与肌张力障碍有关的电压门控钠通道 Nav1.4 变体的生物物理机制多种多样。

编码 Nav1.4 通道 α-亚基的 SCN4A 基因突变可导致肌张力障碍或瘫痪等神经肌肉疾病。在这里，我们研究了通道 DIII-IV 环中 K1302Q 和 G1306E 这两个氨基酸置换的影响，它们与肌张力障碍患者中发现的突变相对应。我们将临床、电生理学和分子建模数据结合在一起，为突变通道的分子机制以及最终导致病理的分子机制提供了一个整体图景。我们分析了 K1302Q 替代患者的现有临床数据，这些数据被报告用于有或无肌张力障碍表型的成人患者，并报告了两名新的无关的 G1306E 替代患者，他们表现为严重的新生儿发作性喉痉挛和儿童期肌张力障碍。我们通过在爪蟾卵母细胞中表达 Nav1.4 α 亚基和 β1 亚基，并使用双电极电压钳记录钠电流，对突变通道进行了功能分析。K1302Q 变体表现出稳态快速失活的异常电压依赖性，这可能是导致病变的原因。与 G1306E 等其他几种肌强直突变不同，K1302Q 不会导致减速的快速失活。对于这两种突变体，我们都观察到了窗口电流的增加，这与可用于激活的通道数量增加相对应。为了阐述实验数据的结构原理，我们探讨了野生型 Nav1.4 的 AlphaFold2 模型和突变体通道的蒙特卡罗最小化模型中涉及 K/Q1302 和 E1306 的接触。我们的数据为支持 K1302Q 变异可能致病的分类提供了缺失的证据，可供临床医生使用。

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

FASEB Journal 生物-生化与分子生物学

CiteScore

9.20

自引率

2.10%

发文量

6243

审稿时长

3 months

期刊介绍： The FASEB Journal publishes international, transdisciplinary research covering all fields of biology at every level of organization: atomic, molecular, cell, tissue, organ, organismic and population. While the journal strives to include research that cuts across the biological sciences, it also considers submissions that lie within one field, but may have implications for other fields as well. The journal seeks to publish basic and translational research, but also welcomes reports of pre-clinical and early clinical research. In addition to research, review, and hypothesis submissions, The FASEB Journal also seeks perspectives, commentaries, book reviews, and similar content related to the life sciences in its Up Front section.