Putting on molecular weight: Enabling cryo-EM structure determination of sub-100-kDa proteins

IF 2.7 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Current Research in Structural Biology Pub Date : 2022-01-01 DOI:10.1016/j.crstbi.2022.09.005

Koen Wentinck , Christos Gogou , Dimphna H. Meijer

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引用次数: 5

Abstract

Significant advances in the past decade have enabled high-resolution structure determination of a vast variety of proteins by cryogenic electron microscopy single particle analysis. Despite improved sample preparation, next-generation imaging hardware, and advanced single particle analysis algorithms, small proteins remain elusive for reconstruction due to low signal-to-noise and lack of distinctive structural features. Multiple efforts have therefore been directed at the development of size-increase techniques for small proteins. Here we review the latest methods for increasing effective molecular weight of proteins <100 kDa through target protein binding or target protein fusion - specifically by using nanobody-based assemblies, fusion tags, and symmetric scaffolds. Finally, we summarize these state-of-the-art techniques into a decision-tree to facilitate the design of tailored future approaches, and thus for further exploration of ever-smaller proteins that make up the largest part of the human genome.

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增加分子量:使低温电镜结构测定低于100 kda的蛋白质

在过去的十年中，通过低温电子显微镜单粒子分析，可以对多种蛋白质进行高分辨率结构测定。尽管改进了样品制备，下一代成像硬件和先进的单颗粒分析算法，但由于低信噪比和缺乏独特的结构特征，小蛋白质仍然难以重建。因此，多种努力都是针对小蛋白质的尺寸增加技术的发展。在这里，我们回顾了通过靶蛋白结合或靶蛋白融合(特别是使用基于纳米体的组件、融合标签和对称支架)来增加蛋白质有效分子量(100 kDa)的最新方法。最后，我们将这些最先进的技术总结为一个决策树，以促进设计量身定制的未来方法，从而进一步探索构成人类基因组最大部分的更小的蛋白质。

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