Substrate Specificity and Kinetics of RNA Hydrolysis by SARS-CoV-2 NSP10/14 Exonuclease

IF 3.8 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Tyler L. Dangerfield,  and , Kenneth A. Johnson*, 
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引用次数: 0

Abstract

Severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2), the virus that causes COVID-19, continues to evolve resistance to vaccines and existing antiviral therapies at an alarming rate, increasing the need for new direct-acting antiviral drugs. Despite significant advances in our fundamental understanding of the kinetics and mechanism of viral RNA replication, there are still open questions regarding how the proofreading exonuclease (NSP10/NSP14 complex) contributes to replication fidelity and resistance to nucleoside analogs. Through single turnover kinetic analysis, we show that the preferred substrate for the exonuclease is double-stranded RNA without any mismatches. Double-stranded RNA containing a 3′-terminal remdesivir was hydrolyzed at a rate similar to a correctly base-paired cognate nucleotide. Surprisingly, single-stranded RNA or duplex RNA containing a 3′-terminal mismatch was hydrolyzed at rates 125- and 45-fold slower, respectively, compared to the correctly base-paired double-stranded RNA. These results define the substrate specificity and rate of removal of remdesivir for the exonuclease and outline rigorous kinetic assays that could help in finding next-generation exonuclease inhibitors or nucleoside analogs that are able to evade excision. These results also raise important questions about the role of the polymerase/exonuclease complex in proofreading during viral replication. Addressing these questions through rigorous kinetic analysis will facilitate the search for desperately needed antiviral drugs to combat COVID-19.

Abstract Image

SARS-CoV-2 NSP10/14核酸外切酶水解RNA的底物特异性和动力学
导致COVID-19的严重急性呼吸综合征冠状病毒-2 (SARS-CoV-2)继续以惊人的速度进化出对疫苗和现有抗病毒疗法的耐药性,从而增加了对新型直接作用抗病毒药物的需求。尽管我们对病毒RNA复制动力学和机制的基本理解取得了重大进展,但关于校对外切酶(NSP10/NSP14复合物)如何有助于复制保真度和对核苷类似物的抗性,仍然存在悬而未决的问题。通过单次翻转动力学分析,我们发现外切酶的首选底物是双链RNA,没有任何错配。含有3 '端remdesivir的双链RNA以与碱基配对的同源核苷酸相似的速率水解。令人惊讶的是,与碱基配对正确的双链RNA相比,含有3 '端不匹配的单链RNA或双链RNA的水解速度分别慢125倍和45倍。这些结果定义了底物特异性和瑞德西韦对外切酶的去除率,并概述了严格的动力学分析,可以帮助寻找下一代外切酶抑制剂或核苷类似物,能够逃避切除。这些结果也提出了关于聚合酶/核酸外切酶复合物在病毒复制过程中的校对作用的重要问题。通过严格的动力学分析解决这些问题将有助于寻找抗击COVID-19迫切需要的抗病毒药物。
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来源期刊
ACS Bio & Med Chem Au
ACS Bio & Med Chem Au 药物、生物、化学-
CiteScore
4.10
自引率
0.00%
发文量
0
期刊介绍: ACS Bio & Med Chem Au is a broad scope open access journal which publishes short letters comprehensive articles reviews and perspectives in all aspects of biological and medicinal chemistry. Studies providing fundamental insights or describing novel syntheses as well as clinical or other applications-based work are welcomed.This broad scope includes experimental and theoretical studies on the chemical physical mechanistic and/or structural basis of biological or cell function in all domains of life. It encompasses the fields of chemical biology synthetic biology disease biology cell biology agriculture and food natural products research nucleic acid biology neuroscience structural biology and biophysics.The journal publishes studies that pertain to a broad range of medicinal chemistry including compound design and optimization biological evaluation molecular mechanistic understanding of drug delivery and drug delivery systems imaging agents and pharmacology and translational science of both small and large bioactive molecules. Novel computational cheminformatics and structural studies for the identification (or structure-activity relationship analysis) of bioactive molecules ligands and their targets are also welcome. The journal will consider computational studies applying established computational methods but only in combination with novel and original experimental data (e.g. in cases where new compounds have been designed and tested).Also included in the scope of the journal are articles relating to infectious diseases research on pathogens host-pathogen interactions therapeutics diagnostics vaccines drug-delivery systems and other biomedical technology development pertaining to infectious diseases.
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