Abolished frameshifting for predicted structure-stabilizing SARS-CoV-2 mutants: implications to alternative conformations and their statistical structural analyses.

IF 4.2 3区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

RNA Pub Date : 2024-10-16 DOI:10.1261/rna.080035.124

Abhishek Dey, Shuting Yan, Tamar Schlick, Alain Laederach

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引用次数: 0

Abstract

The SARS-CoV-2 frameshifting element (FSE) has been intensely studied and explored as a therapeutic target for coronavirus diseases, including COVID-19. Besides the intriguing virology, this small RNA is known to adopt many length-dependent conformations, as verified by multiple experimental and computational approaches. However, the role these alternative conformations play in the frameshifting mechanism and how to quantify this structural abundance has been an ongoing challenge. Here, we show by DMS and dual-luciferase functional assays that previously predicted FSE mutants (using the RAG graph theory approach) suppress structural transitions and abolish frameshifting. Furthermore, correlated mutation analysis of DMS data by three programs (DREEM, DRACO, and DANCE-MaP) reveals important differences in their estimation of specific RNA conformations, suggesting caution in the interpretation of such complex conformational landscapes. Overall, the abolished frameshifting in three different mutants confirms that all alternative conformations play a role in the pathways of ribosomal transition.

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预测的结构稳定型 SARS-CoV-2 突变体的移帧作用减弱：对替代构象及其统计结构分析的影响

作为冠状病毒疾病（包括 COVID-19）的治疗靶点，SARS-CoV-2 移帧元件（FSE）已被深入研究和探索。除了引人入胜的病毒学之外，通过多种实验和计算方法验证，这种小 RNA 还可采用多种长度依赖性构象。然而，这些替代构象在框架转换机制中的作用以及如何量化这种结构丰度一直是一个挑战。在这里，我们通过 DMS 和双荧光素酶功能测试表明，以前预测的 FSE 突变体（使用 RAG 图论方法）抑制了结构转换并取消了框架转换。此外，通过三种程序（DREEM、DRACO 和 DANCE-MaP）对 DMS 数据进行的相关突变分析表明，它们对特定 RNA 构象的估计存在重大差异，这表明在解释这种复杂的构象景观时需要谨慎。总之，三种不同突变体中帧移动的消失证实，所有替代构象都在核糖体转换的途径中发挥作用。

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

RNA 生物-生化与分子生物学

CiteScore

8.30

自引率

2.20%

发文量

101

审稿时长

2.6 months

期刊介绍： RNA is a monthly journal which provides rapid publication of significant original research in all areas of RNA structure and function in eukaryotic, prokaryotic, and viral systems. It covers a broad range of subjects in RNA research, including: structural analysis by biochemical or biophysical means; mRNA structure, function and biogenesis; alternative processing: cis-acting elements and trans-acting factors; ribosome structure and function; translational control; RNA catalysis; tRNA structure, function, biogenesis and identity; RNA editing; rRNA structure, function and biogenesis; RNA transport and localization; regulatory RNAs; large and small RNP structure, function and biogenesis; viral RNA metabolism; RNA stability and turnover; in vitro evolution; and RNA chemistry.