The conformational landscape of human transthyretin revealed by cryo-EM

Nature structural & molecular biology Pub Date : 2025-01-22 DOI:10.1038/s41594-024-01472-7

Benjamin Basanta, Karina Nugroho, Nicholas L. Yan, Gabriel M. Kline, Evan T. Powers, Felix J. Tsai, Mengyu Wu, Althea Hansel-Harris, Jason S. Chen, Stefano Forli, Jeffrey W. Kelly, Gabriel C. Lander

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Abstract

Transthyretin (TTR) is a natively tetrameric thyroxine transporter in blood and cerebrospinal fluid whose misfolding and aggregation causes TTR amyloidosis. A rational drug design campaign identified the small molecule tafamidis (Vyndamax) as a stabilizer of the native TTR fold, and this aggregation inhibitor is regulatory agency approved for the treatment of TTR amyloidosis. Here we used cryo-EM to investigate the conformational landscape of this 55 kDa tetramer in the absence and presence of one or two ligands, revealing inherent asymmetries in the tetrameric architecture and previously unobserved conformational states. These findings provide critical mechanistic insights into negatively cooperative ligand binding and the structural pathways responsible for TTR amyloidogenesis, underscoring the capacity of cryo-EM to identify pharmacological targets suppressed by the confines of the crystal lattice, opening uncharted territory in structure-based drug design.

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低温电镜显示的人甲状腺素的构象景观

转甲状腺素（TTR）是血液和脑脊液中的一种天然四聚体甲状腺素转运蛋白，其错误折叠和聚集导致TTR淀粉样变性。一项合理的药物设计活动确定了小分子tafamidis （Vyndamax）作为天然TTR折叠的稳定剂，并且该聚集抑制剂被监管机构批准用于治疗TTR淀粉样变性。在这里，我们使用低温电子显微镜研究了这种55 kDa四聚体在缺少或存在一个或两个配体时的构象，揭示了四聚体结构和以前未观察到的构象状态的固有不对称性。这些发现为负合作配体结合和负责TTR淀粉样蛋白形成的结构途径提供了关键的机制见解，强调了低温电镜识别受晶格限制抑制的药理学靶点的能力，为基于结构的药物设计开辟了未知领域。

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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Nature structural & molecular biology

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