Identification of New KCNT1-Epilepsy Drugs by In Silico, Cell, and Drosophila Modeling.

IF 7.7 1区医学 Q1 CLINICAL NEUROLOGY

Annals of Neurology Pub Date : 2025-09-13 DOI:10.1002/ana.78031

Michael G Ricos, Bethan A Cole, Rashid Hussain, Grigori Y Rychkov, Zeeshan Shaukat, Nadia Pilati, Stephen P Muench, Katie J Simmons, Leanne M Dibbens, Jonathan D Lippiat

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引用次数: 0

Abstract

Objective: Hyperactive KCNT1 potassium channels, caused by gain-of-function mutations, are associated with a range of epilepsy disorders. Patients typically experience drug-resistant seizures and, in cases with infantile onset, developmental regression can follow. KCNT1-related disorders include epilepsy of infancy with migrating focal seizures and sleep-related hypermotor epilepsy. There are currently no effective treatments for KCNT1 epilepsies, but suppressing overactive channels poses a potential strategy.

Methods: Using the KCNT1 channel structure we in silico screened a library of known drugs for those predicted to block the channel pore to inhibit channel activity. Cellular KCNT1 channel inhibition was analyzed using electrophysiology and Drosophila bang-sensitive assays were used to analyze seizure suppression. Brain penetration of one drug was analyzed using liquid chromatography-mass spectrometry in a mouse.

Results: Eight known drugs were investigated in vitro for their effects on patient-specific mutant KCNT1 channels, with 4 drugs showing significant reduction of K⁺ current amplitudes. The action of the 4 drugs was then analyzed in vivo and 2 were found to reduce the seizure phenotype in humanized Drosophila KCNT1 epilepsy models. One drug, antrafenine, was shown to cross the blood-brain barrier in mice.

Interpretation: This study identified a known drug, antrafenine, that reduces KCNT1 channel activity, reduces seizure activity in Drosophila, and crosses the blood-brain barrier in the mouse, suggesting its potential applicability as a new treatment for KCNT1 epilepsy. The sequential in silico, in vitro, and in vivo mechanism-based drug selection strategy used here may have broader application for other human disorders where a disease mechanism has been identified. ANN NEUROL 2025.

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通过计算机、细胞和果蝇模型鉴定新的kcnt1 -癫痫药物。

目的：由功能获得突变引起的KCNT1钾通道过度活跃与一系列癫痫疾病有关。患者通常会出现耐药性癫痫发作，在婴儿发病的情况下，可能会出现发育倒退。kcnt1相关疾病包括婴儿期癫痫伴迁移局灶性发作和睡眠相关性运动性癫痫。目前还没有有效的治疗KCNT1癫痫的方法，但抑制过度活跃的通道是一种潜在的策略。方法：利用KCNT1通道结构，我们在计算机上筛选了已知的药物库，预测这些药物可以阻断通道孔以抑制通道活性。细胞KCNT1通道抑制采用电生理学分析，果蝇banga敏感分析癫痫抑制。采用液相色谱-质谱联用技术分析了一种药物在小鼠脑内的渗透作用。结果：我们在体外研究了8种已知药物对患者特异性突变KCNT1通道的影响，其中4种药物可显著降低K+电流幅度。然后在体内分析这4种药物的作用，发现其中2种药物可以降低人源化果蝇KCNT1癫痫模型的发作表型。其中一种药物，安曲宁，在老鼠体内被证明可以穿过血脑屏障。解释：本研究发现了一种已知的药物，antrafenine，可以降低KCNT1通道的活性，降低果蝇的癫痫发作活动，并在小鼠中穿过血脑屏障，表明其作为KCNT1癫痫的新治疗方法的潜在适用性。本文采用的基于计算机、体外和体内机制的顺序药物选择策略，可能在已经确定疾病机制的其他人类疾病中有更广泛的应用。Ann neurol 2025。

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

Annals of Neurology 医学-临床神经学

CiteScore

18.00

自引率

1.80%

发文量

270

审稿时长

3-8 weeks

期刊介绍： Annals of Neurology publishes original articles with potential for high impact in understanding the pathogenesis, clinical and laboratory features, diagnosis, treatment, outcomes and science underlying diseases of the human nervous system. Articles should ideally be of broad interest to the academic neurological community rather than solely to subspecialists in a particular field. Studies involving experimental model system, including those in cell and organ cultures and animals, of direct translational relevance to the understanding of neurological disease are also encouraged.