Interaction with the cysteine-free protein HAX1 expands the substrate specificity and function of MIA40 beyond protein oxidation.

Robin Alexander Rothemann, Dylan Stobbe, Michaela Nicole Hoehne-Wiechmann, Lena Maria Murschall, Esra Peker, Lara Katharina Knaup, Julia Racho, Markus Habich, Sarah Gerlich, Kim Jasmin Lapacz, Kathrin Ulrich, Jan Riemer
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Abstract

The mitochondrial disulphide relay machinery is essential for the import and oxidative folding of many proteins in the mitochondrial intermembrane space. Its core component, the import receptor MIA40 (also CHCHD4), serves as an oxidoreductase but also as a chaperone holdase, which initially interacts with its substrates non-covalently before introducing disulphide bonds for folding and retaining proteins in the intermembrane space. Interactome studies have identified diverse substrates of MIA40, among them the intrinsically disordered HCLS1-associated protein X-1 (HAX1). Interestingly, this protein does not contain cysteines, raising the question of how and to what end HAX1 can interact with MIA40. Here, we demonstrate that MIA40 non-covalently interacts with HAX1 independent of its redox-active cysteines. While HAX1 import is driven by its weak mitochondrial targeting sequence, its subsequent transient interaction with MIA40 stabilizes the protein in the intermembrane space. HAX1 solely depends on the holdase activity of MIA40, and the absence of MIA40 results in the aggregation, degradation and loss of HAX1. Collectively, our study introduces HAX1 as the first endogenous MIA40 substrate without cysteines and demonstrates the diverse functions of this highly conserved oxidoreductase and import receptor.

与无半胱氨酸蛋白 HAX1 的相互作用扩展了 MIA40 的底物特异性和功能,使其超出了蛋白质氧化的范围。
线粒体二硫化物中继机制对于线粒体膜间隙中许多蛋白质的导入和氧化折叠至关重要。它的核心部件--导入受体 MIA40(也称 CHCHD4)--既是氧化还原酶,也是伴侣保持酶,最初与其底物进行非共价相互作用,然后引入二硫键,使蛋白质折叠并保留在膜间隙中。相互作用组研究发现了 MIA40 的多种底物,其中包括内在紊乱的 HCLS1 相关蛋白 X-1(HAX1)。有趣的是,这种蛋白不含半胱氨酸,这就提出了一个问题:HAX1 如何与 MIA40 相互作用以及相互作用的目的是什么?在这里,我们证明了 MIA40 与 HAX1 的非共价相互作用不受其氧化还原活性半胱氨酸的影响。虽然 HAX1 的导入是由其微弱的线粒体靶向序列驱动的,但它随后与 MIA40 的瞬时相互作用使蛋白质稳定在膜间隙中。HAX1 完全依赖于 MIA40 的保持酶活性,而 MIA40 的缺失会导致 HAX1 的聚集、降解和丢失。总之,我们的研究将 HAX1 介绍为第一个不含半胱氨酸的内源性 MIA40 底物,并展示了这种高度保守的氧化还原酶和导入受体的多种功能。
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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