Piezo1 ion channels are capable of conformational signaling.

IF 14.7 1区医学 Q1 NEUROSCIENCES

Neuron Pub Date : 2024-09-25 Epub Date: 2024-07-22 DOI:10.1016/j.neuron.2024.06.024

Amanda H Lewis, Marie E Cronin, Jörg Grandl

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引用次数: 0

Abstract

Piezo1 is a mechanically activated ion channel that senses forces with short latency and high sensitivity. Piezos undergo large conformational changes, induce far-reaching deformation onto the membrane, and modulate the function of two-pore potassium (K_2P) channels. Taken together, this led us to hypothesize that Piezos may be able to signal their conformational state to other nearby proteins. Here, we use chemical control to acutely restrict Piezo1 conformational flexibility and show that Piezo1 conformational changes, but not ion permeation through them, are required for modulating the K_2P channel K_2P2.1 (TREK1). Super-resolution imaging and stochastic simulations further reveal that both channels do not co-localize, which implies that modulation is not mediated through direct binding interactions; however, at high Piezo1 densities, most TREK1 channels are within the predicted Piezo1 membrane footprint, suggesting that the footprint may underlie conformational signaling. We speculate that physiological roles originally attributed to Piezo1 ionotropic function could, alternatively, involve conformational signaling.

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Piezo1 离子通道能够进行构象信号转导。

Piezo1 是一种机械激活的离子通道，能以较短的潜伏期和较高的灵敏度感知外力。Piezos 会发生巨大的构象变化，导致膜发生深远的变形，并调节双孔钾（K2P）通道的功能。综上所述，我们推测 Piezos 可能能够向附近的其他蛋白质发出构象状态信号。在这里，我们利用化学控制来急性限制 Piezo1 的构象灵活性，并证明 Piezo1 的构象变化（而非离子通过它们的渗透）是调节 K2P 通道 K2P2.1 (TREK1) 所必需的。超分辨率成像和随机模拟进一步揭示了这两个通道并不共定位，这意味着调制不是通过直接的结合相互作用介导的；然而，在高Piezo1密度下，大多数TREK1通道都在预测的Piezo1膜足迹内，这表明该足迹可能是构象信号转导的基础。我们推测，最初归因于 Piezo1离子传导功能的生理作用可能涉及构象信号转导。

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

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.