Structure–function mapping and mechanistic insights on the SARS CoV2 Nsp1

核酸酶 核糖核酸 CTD公司 DNA 核糖核酸酶 核酸内切酶 C端 生物 化学 细胞生物学 计算生物学 遗传学 基因 核糖核酸酶P 氨基酸 地质学 海洋学
作者
Bruno A. Salgueiro,Margarida Saramago,Mark D. Tully,Cecília M. Arraiano,Elin Moe,Rute G. Matos,Pedro M. Matias,Célia V. Romão
出处
期刊:Protein Science [Wiley]
卷期号:33 (12)
标识
DOI:10.1002/pro.5228
摘要

Abstract Non‐structural protein 1 (Nsp1) is a key component of the infectious process caused by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS‐CoV2), responsible for the COVID‐19 pandemic. Our previous data demonstrated that Nsp1 can degrade both RNA and DNA in the absence of the ribosome, a process dependent on the metal ions Mn 2+ , Ca 2+ , or Mg 2+ (Salgueiro et al., SARS‐CoV2 Nsp1 is a metal‐dependent DNA and RNA endonuclease. Biometals. 2024;37:1127–1146). The protein is composed of two structural domains: the N‐terminal domain (NTD) and C‐terminal domain (CTD), connected by a loop. To elucidate the function of each structural domain, we generated four truncated versions of Nsp1 containing either the NTD or the CTD. Our results indicate that the Nsp1 SARS‐CoV2 domains play distinct functional roles. Specifically, the NTD is involved in nucleotide binding and regulation, while the CTD acts as the catalytic domain. Moreover, a tyrosyl radical was detected during the nuclease activity, and an in‐depth analysis of the different constructs suggested that Y136 could be involved in this process. Indeed, our results show that Y136F Nsp1 variant lacks DNA nuclease activity but retains its RNA nuclease activity. Furthermore, we observed that the CTD has a propensity to associate with hydrophobic environments, suggesting that it might associate with cell membranes. However, the cellular function of this association requires further investigation. This study sheds light on the functions of the individual domains of Nsp1, providing valuable insights into its mechanism of action in Coronaviruses.

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