An asymmetric nautilus-like HflK/C assembly controls FtsH proteolysis of membrane proteins

bioRxiv - Biochemistry Pub Date : 2024-08-10 DOI:10.1101/2024.08.09.604662

Alireza Ghanbarpour, Bertina Telusma, Barrett M. Powell, Jia Jia Zhang, Isabella Bolstad, Carolyn Vargas, Sandro Keller, Tania A. Baker, Robert T. Sauer, Joseph H. Davis

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Abstract

FtsH, a AAA protease, associates with HflK/C subunits to form a megadalton complex that spans the inner membrane and extends into the periplasm of E. coli. How this complex and homologous assemblies in eukaryotic organelles recruit, extract, and degrade membrane-embedded substrates is unclear. Following overproduction of protein components, recent cryo-EM structures reveal symmetric HflK/C cages surrounding FtsH in a manner proposed to inhibit degradation of membrane-embedded substrates. Here, we present structures of native complexes in which HflK/C instead forms an asymmetric nautilus-like assembly with an entryway for membrane-embedded substrates to reach and be engaged by FtsH. Consistent with this nautilus-like structure, proteomic assays suggest that HflK/C enhances FtsH degradation of certain membrane-embedded substrates. Membrane curvature in our FtsH*HflK/C complexes is opposite that of surrounding membrane regions, a property that correlates with lipid-scramblase activity and possibly with FtsH's function in the degradation of membrane-embedded proteins.

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类似鹦鹉螺的不对称 HflK/C 组装控制着膜蛋白的 FtsH 蛋白水解作用

FtsH是一种AAA蛋白酶，它与HflK/C亚基结合形成一个跨越内膜并延伸至大肠杆菌外质的巨核复合体。目前还不清楚这种复合体和真核细胞器中的同源组装体是如何招募、提取和降解膜包底物的。随着蛋白质成分的过度生产，最近的低温电子显微镜结构显示，对称的 HflK/C 笼以抑制膜嵌入底物降解的方式包围了 FtsH。在这里，我们展示了原生复合体的结构，在这种复合体中，HflK/C 形成了一个不对称的鹦鹉螺状组合体，其中有一个入口供膜埋底物到达并被 FtsH 激活。与这种鹦鹉螺状结构相一致的是，蛋白质组测定表明，HflK/C 能增强 FtsH 对某些膜嵌入底物的降解作用。在我们的 FtsH*HflK/C 复合物中，膜曲率与周围膜区域的曲率相反，这种特性与脂质鳞片酶的活性有关，也可能与 FtsH 降解膜嵌入蛋白的功能有关。

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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bioRxiv - Biochemistry

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