Analysis of epilepsy-associated variants in HCN3 – Functional implications and clinical observations

IF 2.8 3区医学 Q2 CLINICAL NEUROLOGY

Epilepsia Open Pub Date : 2024-10-03 DOI:10.1002/epi4.13049

Peiwei Zhao, Hongbo Xiong, Gunagtao Kuang, Chen Sun, Xiankai Zhang, Yufeng Huang, Sukun Luo, Lei Zhang, Jun Jiang, Xuelian He

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Abstract

Objective

This case study investigates the role of hyperpolarization-activated, cyclic nucleotide-gated (HCN) ion channels, which are integral membrane proteins crucial for regulating neuronal excitability. HCN channels are composed of four subunits (HCN1-4), with HCN1, HCN2, and HCN4 previously linked to epilepsy. However, the role of the HCN3 in epileptogenesis remains underexplored.

Methods

We recruited a cohort of 298 epilepsy patients to screen for genetic variants in the HCN3 (NM_020897.3) using Sanger sequencing. We identified rare variants and conducted functional assays to evaluate their pathogenicity.

Results

We identified three rare heterozygous variants in HCN3: c.1370G > A (R457H), c.1982G > A (R661Q), and c.1982G > A(P630L). In vitro functional analyses demonstrated that these variants affected the expression level of HCN3 protein without altering its membrane localization. Whole-cell voltage-clamp experiments showed that two variants (R457H and R661Q) significantly reduced current density in cells, while P630L has no effect on ion channel current.

Significance

Our findings suggest that the identified HCN3 genetic variants disrupt HCN ion channel function, highlighting HCN3 as a novel candidate gene involved in epileptic disorders. This expands the genetic landscape of epilepsy and provides new insights into its molecular underpinnings.

Plain Language Summary

Epilepsy is a brain disease that can be caused by mutations in specific genes. We found three rare variants in HCN3 gene in 298 patients with epilepsy, and two of the three mutations could be pathogenic and cause epilepsy and another one is single-nucleotide polymorphism, which could have no effect and no contribution to the development of epilepsy.

Abstract Image

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与癫痫相关的 HCN3 变异分析 - 功能影响和临床观察。

研究目的本病例研究调查了超极化激活的环核苷酸门控（HCN）离子通道的作用。HCN 通道由四个亚基（HCN1-4）组成，其中 HCN1、HCN2 和 HCN4 以前与癫痫有关。然而，HCN3 在癫痫发生中的作用仍未得到充分探索：我们招募了 298 名癫痫患者，利用桑格测序筛选 HCN3 (NM_020897.3) 的遗传变异。我们确定了罕见变异，并进行了功能测定以评估其致病性：结果：我们发现了 HCN3 中的三个罕见杂合变异：c.1370G > A (R457H)、c.1982G > A (R661Q) 和 c.1982G > A(P630L)。体外功能分析表明，这些变体影响了 HCN3 蛋白的表达水平，但没有改变其膜定位。全细胞电压钳实验表明，两个变体（R457H 和 R661Q）显著降低了细胞中的电流密度，而 P630L 对离子通道电流没有影响：我们的研究结果表明，已发现的HCN3基因变异会破坏HCN离子通道的功能，这凸显了HCN3是一种与癫痫疾病有关的新型候选基因。这拓展了癫痫的遗传图谱，并为了解其分子基础提供了新的视角。原文摘要：癫痫是一种可由特定基因突变引起的脑部疾病。我们在298名癫痫患者中发现了HCN3基因的三个罕见变异，其中两个变异可能是致病性的，会导致癫痫，另一个是单核苷酸多态性，可能对癫痫的发生没有影响，也没有贡献。

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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