相邻核糖体翻译的新生蛋白之间的相互作用驱动同源寡聚体的组装。
Interactions between nascent proteins translated by adjacent ribosomes drive homomer assembly.
机构信息
Center for Molecular Biology of Heidelberg University (ZMBH) and German Cancer Research Center (DKFZ), DKFZ-ZMBH Alliance, Im Neuenheimer Feld 282, Heidelberg D-69120, Germany.
AMOLF, Science Park 104, 1098 XG Amsterdam, Netherlands.
出版信息
Science. 2021 Jan 1;371(6524):57-64. doi: 10.1126/science.abc7151.
Abstract
Accurate assembly of newly synthesized proteins into functional oligomers is crucial for cell activity. In this study, we investigated whether direct interaction of two nascent proteins, emerging from nearby ribosomes (co-co assembly), constitutes a general mechanism for oligomer formation. We used proteome-wide screening to detect nascent chain-connected ribosome pairs and identified hundreds of homomer subunits that co-co assemble in human cells. Interactions are mediated by five major domain classes, among which N-terminal coiled coils are the most prevalent. We were able to reconstitute co-co assembly of nuclear lamin in , demonstrating that dimer formation is independent of dedicated assembly machineries. Co-co assembly may thus represent an efficient way to limit protein aggregation risks posed by diffusion-driven assembly routes and ensure isoform-specific homomer formation.
摘要
新合成蛋白质准确组装成功能性寡聚体对于细胞活动至关重要。在这项研究中,我们研究了两个新合成蛋白质(共翻译组装)是否直接相互作用构成寡聚体形成的一般机制。我们使用蛋白质组范围的筛选来检测来自附近核糖体的新生链连接核糖体对,并在人类细胞中鉴定了数百个同源亚基共组装。相互作用由五个主要结构域类介导,其中 N 端卷曲螺旋最为普遍。我们能够重建核层粘连蛋白的共翻译组装,证明二聚体形成不依赖于专用组装机制。因此,共翻译组装可能代表一种有效方式,可以限制扩散驱动组装途径带来的蛋白质聚集风险,并确保同种型特异性同源组装的形成。
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2
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Cell. 2019 Oct 17;179(3):671-686.e17. doi: 10.1016/j.cell.2019.09.022.
3
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Nat Protoc. 2019 Aug;14(8):2279-2317. doi: 10.1038/s41596-019-0185-z. Epub 2019 Jul 22.
4
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5
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6
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