Vipp1 螺旋形成、环状生物生成和膜修复的机制

Souvik Naskar, Andrea Merino, Javier Espadas, Jayanti Singh, Aurelien Roux, Adai Colom, Harry H. Low
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摘要

类 ESCRT-III 蛋白 Vipp1 将丝状体聚合与膜重塑结合在一起。它既能组装平面薄片,也能组装三维环和螺旋聚合物,这些都与减轻质体相关膜应力有关。Vipp1 平面片材和螺旋聚合物的结构以及在聚合物形态之间转换所需的几何变化仍然未知。在这里,我们展示了蓝藻 Vipp1 如何在体外膜上组装成形态相关的片状和螺旋状。螺旋汇聚形成的中心环与膜出芽中描述的中心环相似。螺旋丝的低温电子显微镜(Cryo-EM)结构揭示了 Vipp1 螺旋晶格与平面晶格之间密切的几何关系。此外,螺旋结构还揭示了丝是如何扭转的--这是 Vipp1 和其他 ESCRT-III 丝在平面和三维结构之间转换所需的过程。总之,我们的研究结果为 Vipp1 环的生物生成提供了一个分子模型,并为 Vipp1 膜的稳定和修复提供了一种机制,这对其他 ESCRT-III 系统也有影响。
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Mechanism for Vipp1 spiral formation, ring biogenesis, and membrane repair

The ESCRT-III-like protein Vipp1 couples filament polymerization with membrane remodeling. It assembles planar sheets as well as 3D rings and helical polymers, all implicated in mitigating plastid-associated membrane stress. The architecture of Vipp1 planar sheets and helical polymers remains unknown, as do the geometric changes required to transition between polymeric forms. Here we show how cyanobacterial Vipp1 assembles into morphologically-related sheets and spirals on membranes in vitro. The spirals converge to form a central ring similar to those described in membrane budding. Cryo-EM structures of helical filaments reveal a close geometric relationship between Vipp1 helical and planar lattices. Moreover, the helical structures reveal how filaments twist—a process required for Vipp1, and likely other ESCRT-III filaments, to transition between planar and 3D architectures. Overall, our results provide a molecular model for Vipp1 ring biogenesis and a mechanism for Vipp1 membrane stabilization and repair, with implications for other ESCRT-III systems.

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