Important amino acid residues in the chloride pump halorhodopsin that accelerate ion transport despite no direct interaction with the substrate.

IF 4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biological Chemistry Pub Date : 2025-09-11 DOI:10.1016/j.jbc.2025.110703

Yubo Zhai,Anna Shimosaka,Takashi Tsukamoto,Takashi Kikukawa

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引用次数: 0

Abstract

Ion-pump rhodopsins are widely distributed photoactive membrane proteins found in microorganisms. Their cytoplasmic (CP) regions are predominantly hydrophobic, inherently restricting substrate ion permeation. However, these rhodopsins can rapidly transport substrate ions via photo-induced conformational changes. The well-characterized H+-pumping rhodopsins employ dissociable residues such as Asp, Glu, or Lys to mediate rapid H+ relay reactions along a transiently hydrated CP pathway. In contrast, the corresponding mechanisms in other ion pumps remain poorly understood. Here, we investigated the key factors contributing to ion transport by halorhodopsin (HR), a Cl- pump from the archaeon Natronomonas pharaonis (NpHR). Upon photoactivation, NpHR creates a hydrated Cl- transport pathway in its CP region, which is surrounded by bulky hydrophobic residues that do not directly interact with Cl-. However, mutations in specific hydrophobic residues significantly slow Cl- transport. Notably, Phe211 and Leu214, located near the pathway exit, play critical roles. Mutations in these residues likely disrupt the proper positioning of the Lys215 sidechain, which inadvertently binds Cl- from the surrounding solution and positions it in a way that obstructs Cl- transport. As a result, ion passage is hindered, leading to the accumulation of long-lived intermediates. These findings suggest that the hydrophobic residues surrounding the pathway are not merely structural components. Instead, they are critical for enabling specific conformational changes that facilitate the formation of a hydrated channel, allowing efficient Cl- conduction without obstruction.

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尽管与底物没有直接的相互作用，但氯泵盐紫红质中加速离子运输的重要氨基酸残基。

离子泵视紫红质是广泛存在于微生物中的光活性膜蛋白。它们的细胞质（CP）区域主要是疏水的，固有地限制了底物离子的渗透。然而，这些视紫红质可以通过光诱导的构象变化快速运输底物离子。表征良好的H+泵送视紫红质利用可解离残基如Asp， Glu或Lys来介导沿瞬时水合CP途径的快速H+接力反应。相比之下，其他离子泵的相应机制仍然知之甚少。本文研究了古细菌法老钠单胞菌（NpHR）的一种Cl-泵——盐紫红质（HR）对离子运输的关键影响因素。在光激活后，NpHR在其CP区域产生水合Cl-运输途径，该区域被不直接与Cl-相互作用的大块疏水残基包围。然而，特定疏水残基的突变显著减缓了Cl-转运。值得注意的是，位于通路出口附近的Phe211和Leu214发挥了关键作用。这些残基的突变可能会破坏Lys215侧链的正确定位，从而无意中与周围溶液中的Cl-结合，并以阻碍Cl-运输的方式定位。结果，离子通过受阻，导致长寿命中间体的积累。这些发现表明，该途径周围的疏水残基不仅仅是结构成分。相反，它们对于促进水合通道形成的特定构象变化至关重要，从而使Cl-无阻碍地有效传导。

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

Journal of Biological Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry

自引率

4.20%

发文量

1233

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