FUS 通过 LLPS 介导的 MEF2 和 ETV5 招募控制肌肉分化和结构

Gina Picchiarelli, Anne Wienand, Salim Megat, Amr Aly, Marije Been, Nibha Mishra, Saskia Hutten, Erin Sternburg, Pierre Cauchy, Stephane Dieterle, Marica Catinozzi, Valerie Demais, Laura Tzeplaeff, Annemarie Huebers, Dagmar Zeuschner, Angela Rosenbohm, Albert C Ludolph, Anne-Laurence Boutillier, Tobias Boeckers, Dorothee Dormann, Maria Demestre, Chantal Sellier, Clotilde Lagier-Tourenne, Erik Storkebaum, Luc Dupuis
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引用次数: 0

摘要

肌萎缩性脊髓侧索硬化症(ALS)是一种神经退行性疾病,以进行性肌无力为特征。我们的研究表明,与 ALS 相关的 FUS 基因突变会导致 FUS-ALS 患者的肌肉出现超微结构缺陷,肌节和线粒体受到破坏。对小鼠和果蝇模型的研究表明,FUS在肌肉发育过程中具有进化保守的细胞自主功能。从机制上讲,FUS 是 MEF2 依赖基因转录所必需的,它与 ETS 转录因子(尤其是 ETV5)结合的基因启动子结合,并与 ETV5 共同激活 MEF2 依赖基因的转录。FUS 与 ETV5 和 MEF2A 相分离,MEF2A 与 FUS 的结合受到 ETV5 的促进。最后,在 FUS-ALS 小鼠模型中,Etv5 单倍性缺失会加重肌无力。这些发现确定了 FUS 是骨骼肌结构的必需蛋白,它通过相分离依赖性招募 ETV5 和 MEF2,定义了在 FUS-ALS 中受损的新途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
FUS controls muscle differentiation and structure through LLPS mediated recruitment of MEF2 and ETV5
FUS is an RNA binding protein mutated in amyotrophic lateral sclerosis (ALS), a neurodegenerative disease characterized by progressive muscle weakness. We show that ALS-associated FUS mutations lead to ultrastructural defects in muscle of FUS-ALS patients, with disruption of sarcomeres and mitochondria. Studies in mouse and Drosophila models demonstrate an evolutionary-conserved cell autonomous function of FUS in muscle development. Mechanistically, FUS is required for transcription of MEF2 dependent genes, binds to the promoter of genes bound by ETS transcription factors in particular ETV5 and co-activates transcription of MEF2 dependent genes with ETV5. FUS phase separates with ETV5 and MEF2A, and MEF2A binding to FUS is potentiated by ETV5. Last, Etv5 haploinsufficiency exacerbates muscle weakness in a mouse model of FUS-ALS. These findings establish FUS as an essential protein for skeletal muscle structure through its phase separation-dependent recruitment of ETV5 and MEF2, defining a novel pathway compromised in FUS-ALS.
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