自噬
细胞生物学
生物发生
细胞质
内质网
生物
袋3
细胞器
化学
生物化学
基因
细胞凋亡
作者
Mariya Licheva,Jeremy Pflaum,Riccardo Babic,Héctor Mancilla,Jana Elsaesser,Emily Boyle,David M. Hollenstein,Jorge Jimenez-Niebla,Jonas Pleyer,Maria Heinrich,Franz-Georg Wieland,Joachim Brenneisen,Christopher Eickhorst,Johann Brenner,Shan Jiang,Markus Hartl,Sonja Welsch,Carola Hunte,Jens Timmer,Florian Wilfling
标识
DOI:10.1038/s41556-024-01572-y
摘要
Autophagy is a key cellular quality control mechanism. Nutrient stress triggers bulk autophagy, which nonselectively degrades cytoplasmic material upon formation and liquid-liquid phase separation of the autophagy-related gene 1 (Atg1) complex. In contrast, selective autophagy eliminates protein aggregates, damaged organelles and other cargoes that are targeted by an autophagy receptor. Phase separation of cargo has been observed, but its regulation and impact on selective autophagy are poorly understood. Here, we find that key autophagy biogenesis factors phase separate into initiation hubs at cargo surfaces in yeast, subsequently maturing into sites that drive phagophore nucleation. This phase separation is dependent on multivalent, low-affinity interactions between autophagy receptors and cargo, creating a dynamic cargo surface. Notably, high-affinity interactions between autophagy receptors and cargo complexes block initiation hub formation and autophagy progression. Using these principles, we converted the mammalian reovirus nonstructural protein µNS, which accumulates as particles in the yeast cytoplasm that are not degraded, into a neo-cargo that is degraded by selective autophagy. We show that initiation hubs also form on the surface of different cargoes in human cells and are key to establish the connection to the endoplasmic reticulum, where the phagophore assembly site is formed to initiate phagophore biogenesis. Overall, our findings suggest that regulated phase separation underscores the initiation of both bulk and selective autophagy in evolutionarily diverse organisms.
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