Atomic structures of FUS LC domain segments reveal bases for reversible amyloid fibril formation.

IF 16.8 1区生物学 Nature Structural &Molecular Biology Pub Date : 2018-04-01 DOI:10.2210/PDB5XRR/PDB

F. Luo, X. Gui, Heng Zhou, Jinge Gu, Yichen Li, Xiangyu Liu, Minglei Zhao, Dan Li, Xueming Li, Cong Liu

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引用次数: 22

Abstract

Thermostable cross-β structures are characteristic of pathological amyloid fibrils, but these structures cannot explain the reversible nature of fibrils formed by RNA-binding proteins such as fused in sarcoma (FUS), involved in RNA granule assembly. Here, we find that two tandem (S/G)Y(S/G) motifs of the human FUS low-complexity domain (FUS LC) form reversible fibrils in a temperature- and phosphorylation-dependent manner. We named these motifs reversible amyloid cores, or RAC1 and RAC2, and determined their atomic structures in fibrillar forms, using microelectron and X-ray diffraction techniques. The RAC1 structure features an ordered-coil fibril spine rather than the extended β-strand typical of amyloids. Ser42, a phosphorylation site of FUS, is critical in the maintenance of the ordered-coil structure, which explains how phosphorylation controls fibril formation. The RAC2 structure shows a labile fibril spine with a wet interface. These structures illuminate the mechanism of reversible fibril formation and dynamic assembly of RNA granules.

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FUS LC结构域片段的原子结构揭示了可逆淀粉样原纤维形成的基础。

热稳定的交叉β结构是病理性淀粉样蛋白原纤维的特征，但这些结构不能解释由RNA结合蛋白形成的原纤维的可逆性质，如参与RNA颗粒组装的融合肉瘤（FUS）。在这里，我们发现人类FUS低复杂度结构域（FUS-LC）的两个串联（S/G）Y（S/G）基序以温度和磷酸化依赖的方式形成可逆的原纤维。我们将这些基序命名为可逆淀粉样蛋白核心，或RAC1和RAC2，并使用微机电和X射线衍射技术确定了它们的原纤维形式的原子结构。RAC1结构具有有序的螺旋原纤维脊，而不是淀粉样蛋白典型的延伸β链。Ser42是FUS的磷酸化位点，在维持有序的螺旋结构中至关重要，这解释了磷酸化如何控制原纤维的形成。RAC2结构显示具有湿界面的不稳定原纤维脊。这些结构阐明了RNA颗粒的可逆原纤维形成和动态组装的机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nature Structural &Molecular Biology 生物-生化与分子生物学

自引率

1.80%

发文量

160

期刊介绍： Nature Structural & Molecular Biology is a monthly journal that focuses on the functional and mechanistic understanding of how molecular components in a biological process work together. It serves as an integrated forum for structural and molecular studies. The journal places a strong emphasis on the functional and mechanistic understanding of how molecular components in a biological process work together. Some specific areas of interest include the structure and function of proteins, nucleic acids, and other macromolecules, DNA replication, repair and recombination, transcription, regulation of transcription and translation, protein folding, processing and degradation, signal transduction, and intracellular signaling.