Human TMC1 and TMC2 are mechanically gated ion channels.

IF 14.7 1区 医学 Q1 NEUROSCIENCES
Songdi Fu, Xueqi Pan, Mingshun Lu, Jianying Dong, Zhiqiang Yan
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引用次数: 0

Abstract

Mammalian transmembrane channel-like proteins 1 and 2 (TMC1 and TMC2) have emerged as very promising candidate mechanotransduction channels in hair cells. However, controversy persists because the heterogeneously expressed TMC1/2 in cultured cells lack evidence of mechanical gating, primarily due to their absence from the plasma membrane. By employing domain swapping with OSCA1.1 and subsequent point mutations, we successfully identified membrane-localized mouse TMC1/2 mutants, demonstrating that they are mechanically gated in heterologous cells. Further, whole-genome CRISPRi screening enabled wild-type human TMC1/2 localization in the plasma membrane, where they responded robustly to poking stimuli. In addition, wild-type human TMC1/2 showed stretch-activated currents and clear single-channel current activities. Deafness-related TMC1 mutations altered the reversal potential of TMC1, indicating that TMC1/2 are pore-forming mechanotransduction channels. In summary, our study provides evidence that human TMC1/2 are pore-forming, mechanically activated ion channels, supporting their roles as mechanotransduction channels in hair cells.

人类 TMC1 和 TMC2 是机械门控离子通道。
哺乳动物跨膜通道样蛋白 1 和 2(TMC1 和 TMC2)已成为毛细胞中非常有前途的候选机械传导通道。然而,由于培养细胞中异质性表达的 TMC1/2 缺乏机械门控的证据,主要是因为它们不在质膜上,因此争议一直存在。通过与 OSCA1.1 进行结构域交换以及随后的点突变,我们成功鉴定了膜定位的小鼠 TMC1/2 突变体,证明它们在异源细胞中具有机械门控功能。此外,全基因组 CRISPRi 筛选使野生型人类 TMC1/2 定位于质膜,在质膜上它们对戳刺刺激有很强的反应。此外,野生型人类 TMC1/2 还显示出拉伸激活电流和清晰的单通道电流活动。与耳聋相关的 TMC1 突变改变了 TMC1 的反转电位,表明 TMC1/2 是孔形成的机械传导通道。总之,我们的研究提供了人类 TMC1/2 是孔形成的机械激活离子通道的证据,支持它们在毛细胞中作为机械传导通道的作用。
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来源期刊
Neuron
Neuron 医学-神经科学
CiteScore
24.50
自引率
3.10%
发文量
382
审稿时长
1 months
期刊介绍: Established as a highly influential journal in neuroscience, Neuron is widely relied upon in the field. The editors adopt interdisciplinary strategies, integrating biophysical, cellular, developmental, and molecular approaches alongside a systems approach to sensory, motor, and higher-order cognitive functions. Serving as a premier intellectual forum, Neuron holds a prominent position in the entire neuroscience community.
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