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Literature DB >> 35477997

Myosin 1D and the branched actin network control the condensation of p62 bodies.

Xuezhao Feng^1,2, Wanqing Du³, Mingrui Ding⁴, Wenkang Zhao³, Xirenayi Xirefu^1,5, Meisheng Ma⁶, Yuhui Zhuang⁷, Xiaoyu Fu⁸, Jiangfeng Shen⁷, Jinpei Zhang^1,2, Xiuying Lei^1,2, Daxiao Sun³, Qing Xi^1,2, Yiliyasi Aisa^1,5, Qian Chen^1,2, Ying Li^3,9, Wenjuan Wang⁹, Shanjin Huang⁷, Li Yu³, Pilong Li¹⁰, Na Mi¹¹.

Abstract

Biomolecular condensation driven by liquid-liquid phase separation (LLPS) is key to assembly of membraneless organelles in numerous crucial pathways. It is largely unknown how cellular structures or components spatiotemporally regulate LLPS and condensate formation. Here we reveal that cytoskeletal dynamics can control the condensation of p62 bodies comprising the autophagic adaptor p62/SQSTM1 and poly-ubiquitinated cargos. Branched actin networks are associated with p62 bodies and are required for their condensation. Myosin 1D, a branched actin-associated motor protein, drives coalescence of small nanoscale p62 bodies into large micron-scale condensates along the branched actin network. Impairment of actin cytoskeletal networks compromises the condensation of p62 bodies and retards substrate degradation by autophagy in both cellular models and Myosin 1D knockout mice. Coupling of LLPS scaffold to cytoskeleton systems may represent a general mechanism by which cells exert spatiotemporal control over phase condensation processes.

Entities: Chemical

Mesh：

Substances：

Year: 2022 PMID： 35477997 PMCID： PMC9253125 DOI： 10.1038/s41422-022-00662-6

Source DB: PubMed Journal: Cell Res ISSN： 1001-0602 Impact factor: 46.297

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