Nanobodies against Cavin1 reveal structural flexibility and regulated interactions of its N-terminal coiled-coil domain.

IF 3.3 3区生物学 Q3 CELL BIOLOGY

Journal of cell science Pub Date : 2025-04-15 Epub Date: 2025-04-28 DOI:10.1242/jcs.263756

Ya Gao, Vikas A Tillu, Yeping Wu, James Rae, Thomas E Hall, Kai-En Chen, Saroja Weeratunga, Qian Guo, Emma Livingstone, Wai-Hong Tham, Robert G Parton, Brett M Collins

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Abstract

Caveolae are abundant plasma membrane structures that regulate signalling, membrane homeostasis and mechanoprotection. Their formation is driven by caveolins and cavins and their coordinated interactions with lipids. Here, we developed nanobodies against the trimeric HR1 coiled-coil domain of Cavin1. We identified specific nanobodies that do not perturb Cavin1 membrane binding and localise to caveolae when expressed in cells. The crystal structure of a nanobody-Cavin 1 HR1 complex reveals a symmetric 3:3 architecture as validated by mutagenesis. In this structure, the C-terminal half of the HR1 domain is disordered, suggesting that the nanobody stabilises an open conformation of Cavin1, which has previously been identified as important for membrane interactions. A phosphomimic mutation in a threonine-serine pair proximal to this region reveals selective regulation of Cavin2 and Cavin3 association. These studies provide new insights into cavin domains required for assembly of multiprotein caveolar assemblies and describe new nanobody tools for structural and functional studies of caveolae.

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抗Cavin1的纳米体揭示了其n端线圈结构域的结构灵活性和调节的相互作用。

小泡是一种丰富的质膜结构，具有信号传导、膜稳态和机械保护等功能。它们的形成是由小洞蛋白和小洞蛋白以及它们与脂质的协调相互作用驱动的。在这里，我们开发了针对Cavin1的三聚体HR1卷曲结构域的纳米体。我们确定了不干扰Cavin1膜结合并在细胞中表达时定位于小泡的特定纳米体。纳米体- cavin 1 HR1复合物的晶体结构通过诱变证实为对称的3:3结构。在这个结构中，HR1结构域的c端一半是无序的，这表明纳米体稳定了Cavin1的开放构象，这在之前被认为是膜相互作用的重要因素。该区域近端苏氨酸-丝氨酸对的磷酰亚胺突变揭示了Cavin2和Cavin3关联的选择性调控。这些研究为研究多蛋白腔泡组装所需的腔洞结构域提供了新的见解，并描述了用于腔泡结构和功能研究的新纳米体工具。

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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