RNA sample optimization for cryo-EM analysis.

IF 13.1 1区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS Nature Protocols Pub Date : 2024-11-15 DOI:10.1038/s41596-024-01072-1
Xingyu Chen, Liu Wang, Jiahao Xie, Jakub S Nowak, Bingnan Luo, Chong Zhang, Guowen Jia, Jian Zou, Dingming Huang, Sebastian Glatt, Yang Yang, Zhaoming Su
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Abstract

RNAs play critical roles in most biological processes. Although the three-dimensional (3D) structures of RNAs primarily determine their functions, it remains challenging to experimentally determine these 3D structures due to their conformational heterogeneity and intrinsic dynamics. Cryogenic electron microscopy (cryo-EM) has recently played an emerging role in resolving dynamic conformational changes and understanding structure-function relationships of RNAs including ribozymes, riboswitches and bacterial and viral noncoding RNAs. A variety of methods and pipelines have been developed to facilitate cryo-EM structure determination of challenging RNA targets with small molecular weights at subnanometer to near-atomic resolutions. While a wide range of conditions have been used to prepare RNAs for cryo-EM analysis, correlations between the variables in these conditions and cryo-EM visualizations and reconstructions remain underexplored, which continue to hinder optimizations of RNA samples for high-resolution cryo-EM structure determination. Here we present a protocol that describes rigorous screenings and iterative optimizations of RNA preparation conditions that facilitate cryo-EM structure determination, supplemented by cryo-EM data processing pipelines that resolve RNA dynamics and conformational changes and RNA modeling algorithms that generate atomic coordinates based on moderate- to high-resolution cryo-EM density maps. The current protocol is designed for users with basic skills and experience in RNA biochemistry, cryo-EM and RNA modeling. The expected time to carry out this protocol may range from 3 days to more than 3 weeks, depending on the many variables described in the protocol. For particularly challenging RNA targets, this protocol could also serve as a starting point for further optimizations.

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优化用于冷冻电镜分析的 RNA 样品。
RNA 在大多数生物过程中发挥着关键作用。虽然 RNA 的三维(3D)结构主要决定了它们的功能,但由于它们的构象异质性和内在动态性,要通过实验确定这些三维结构仍然具有挑战性。最近,低温电子显微镜(cryo-EM)在解析 RNA(包括核酶、核糖开关以及细菌和病毒非编码 RNA)的动态构象变化和理解其结构与功能的关系方面发挥了新兴作用。目前已开发出多种方法和流水线,以促进以亚纳米到近原子分辨率对具有挑战性的小分子量 RNA 目标进行低温电子显微镜结构测定。虽然有多种条件可用于制备 RNA 以进行冷冻电镜分析,但这些条件中的变量与冷冻电镜可视化和重建之间的相关性仍未得到充分探索,这继续阻碍着 RNA 样品在高分辨率冷冻电镜结构测定中的优化。在此,我们介绍一种方案,该方案描述了对 RNA 制备条件的严格筛选和迭代优化,以促进冷冻电镜结构测定,并辅以冷冻电镜数据处理管道,以解析 RNA 动态和构象变化,以及根据中高分辨率冷冻电镜密度图生成原子坐标的 RNA 建模算法。目前的方案专为具备 RNA 生物化学、冷冻电镜和 RNA 建模方面基本技能和经验的用户设计。执行该方案的预期时间从 3 天到 3 周以上不等,具体取决于方案中描述的许多变量。对于特别具有挑战性的 RNA 靶标,本方案也可作为进一步优化的起点。
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 Protocols
Nature Protocols 生物-生化研究方法
CiteScore
29.10
自引率
0.70%
发文量
128
审稿时长
4 months
期刊介绍: Nature Protocols focuses on publishing protocols used to address significant biological and biomedical science research questions, including methods grounded in physics and chemistry with practical applications to biological problems. The journal caters to a primary audience of research scientists and, as such, exclusively publishes protocols with research applications. Protocols primarily aimed at influencing patient management and treatment decisions are not featured. The specific techniques covered encompass a wide range, including but not limited to: Biochemistry, Cell biology, Cell culture, Chemical modification, Computational biology, Developmental biology, Epigenomics, Genetic analysis, Genetic modification, Genomics, Imaging, Immunology, Isolation, purification, and separation, Lipidomics, Metabolomics, Microbiology, Model organisms, Nanotechnology, Neuroscience, Nucleic-acid-based molecular biology, Pharmacology, Plant biology, Protein analysis, Proteomics, Spectroscopy, Structural biology, Synthetic chemistry, Tissue culture, Toxicology, and Virology.
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