Asymmetric contribution of a selectivity filter gate in triggering inactivation of CaV1.3 channels.

IF 3.3 2区医学 Q1 PHYSIOLOGY Journal of General Physiology Pub Date : 2024-02-05 Epub Date: 2024-01-04 DOI:10.1085/jgp.202313365

Pedro J Del Rivero Morfin, Audrey L Kochiss, Klaus R Liedl, Bernhard E Flucher, Monica L I Fernández-Quintero, Manu Ben-Johny

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Abstract

Voltage-dependent and Ca2+-dependent inactivation (VDI and CDI, respectively) of CaV channels are two biologically consequential feedback mechanisms that fine-tune Ca2+ entry into neurons and cardiomyocytes. Although known to be initiated by distinct molecular events, how these processes obstruct conduction through the channel pore remains poorly defined. Here, focusing on ultrahighly conserved tryptophan residues in the interdomain interfaces near the selectivity filter of CaV1.3, we demonstrate a critical role for asymmetric conformational changes in mediating VDI and CDI. Specifically, mutagenesis of the domain III-IV interface, but not others, enhanced VDI. Molecular dynamics simulations demonstrate that mutations in distinct selectivity filter interfaces differentially impact conformational flexibility. Furthermore, mutations in distinct domains preferentially disrupt CDI mediated by the N- versus C-lobes of CaM, thus uncovering a scheme of structural bifurcation of CaM signaling. These findings highlight the fundamental importance of the asymmetric arrangement of the pseudotetrameric CaV pore domain for feedback inhibition.

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选择性滤波门在触发 CaV1.3 通道失活过程中的不对称作用

CaV 通道的电压依赖性失活和 Ca2+ 依赖性失活（分别为 VDI 和 CDI）是两种具有生物学意义的反馈机制，可对进入神经元和心肌细胞的 Ca2+ 进行微调。尽管已知这些过程是由不同的分子事件引发的，但这些过程是如何阻碍通道孔传导的，目前仍未明确。在这里，我们重点研究了 CaV1.3 选择性滤波器附近结构域间界面上的超高度保守色氨酸残基，证明了不对称构象变化在介导 VDI 和 CDI 中的关键作用。具体来说，对结构域 III-IV 界面的突变增强了 VDI，而对其他界面的突变则没有增强。分子动力学模拟证明，不同选择性过滤界面的突变对构象灵活性的影响是不同的。此外，不同结构域的突变会优先破坏由 CaM N 环和 C 环介导的 CDI，从而揭示了 CaM 信号转导的结构分叉方案。这些发现凸显了假四聚体 CaV 孔结构域的不对称排列对反馈抑制的根本重要性。

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来源期刊

Journal of General Physiology 医学-生理学

CiteScore

6.00

自引率

10.50%

发文量

审稿时长

6-12 weeks

期刊介绍： General physiology is the study of biological mechanisms through analytical investigations, which decipher the molecular and cellular mechanisms underlying biological function at all levels of organization. The mission of Journal of General Physiology (JGP) is to publish mechanistic and quantitative molecular and cellular physiology of the highest quality, to provide a best-in-class author experience, and to nurture future generations of independent researchers. The major emphasis is on physiological problems at the cellular and molecular level.