确定轮状病毒 NSP4 双层粒子结合域中 169 和 174 氨基酸之间的合作效应。

IF 3.6 4区 医学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Journal of General Virology Pub Date : 2024-09-01 DOI:10.1099/jgv.0.002029
Jayme Herbert, Alberdina A van Dijk
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引用次数: 0

摘要

分段 RNA 病毒能够通过重配交换基因组片段,以此作为逃避免疫和保持病毒活力的一种手段。单基因组片段的重组在 A 组轮状病毒中很常见。在监测中发现,GS6(VP6)和 GS10(NSP4)这两个基因组片段有多次共同重组的情况。具体来说,在 NSP4 双层粒子(DLP)结合域中观察到了 NSP4 基因型之间的分化。之前有人假设这种共重排的机制是 VP6 和 NSP4 在 DLP 从病毒浆液中转运至颗粒成熟过程中的相互作用。在本研究中,我们利用序列分析、RNA 二级结构预测、分子动力学和反向遗传学等方法,对 NSP4 DLP 结合域的作用进行了假设。序列分析表明,在 E1 和 E2 NSP4 基因型之间,NSP4 DLP 结合域氨基酸 169 和 174 的极性明显不同。带有 E1 NSP4 的病毒有 169A/I 或 169S/T 与 174S。E2 NSP4具有169R/K和174A。RNA 二级结构预测显示,545(aa169)和 561(aa174)的突变会导致全局结构重塑。分子动力学显示,通过突变 169 和 174 位的 aa,NSP4/VP6 相互作用的稳定性得到了提高。利用反向遗传学,我们发现仅 R169I 突变并不能阻止救援。相反,将 174A 突变为 174S 可阻止拯救,而将 174S 与 169I 结合可恢复拯救。与rSA11 NSP4-wt相比,rSA11 NSP4-R169I和rSA11 NSP4-R169I/A174S在特定时间点的滴度都有可忽略不计的显著降低。这项研究表明,NSP4的氨基酸174可能是维持DLP转运所需的VP6/NSP4相互作用的关键。我们的研究结果表明,维持 169 和 174 位氨基酸的特定极性可能是轮状病毒野外毒株适应性的必要条件。
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Identification of a cooperative effect between amino acids 169 and 174 in the rotavirus NSP4 double-layered particle-binding domain.

Segmented RNA viruses are capable of exchanging genome segments via reassortment as a means of immune evasion and to maintain viral fitness. Reassortments of single-genome segments are common among group A rotaviruses. Multiple instances of co-reassortment of two genome segments, GS6(VP6) and GS10(NSP4), have been documented in surveillance. Specifically, a division between NSP4 genotypes has been observed in the NSP4 double-layered particle (DLP)-binding domain. A previously hypothesized mechanism for this co-reassortment has been suggested to be the interaction between VP6 and NSP4 during DLP transport from viroplasms for particle maturation. In this study, we used sequence analysis, RNA secondary structure prediction, molecular dynamics and reverse genetics to form a hypothesis regarding the role of the NSP4 DLP-binding domain. Sequence analysis showed that the polarity of NSP4 DLP-binding domain amino acids 169 and 174 is clearly divided between E1 and E2 NSP4 genotypes. Viruses with E1 NSP4s had 169A/I or 169S/T with 174S. E2 NSP4s had 169R/K and 174A. RNA secondary structure prediction showed that mutation in both 545 (aa169) and 561 (aa174) causes global structure remodelling. Molecular dynamics showed that the NSP4/VP6 interaction stability is increased by mutating both aa positions 169 and 174. Using reverse genetics, we showed that an R169I mutation alone does not prevent rescue. Conversely, 174A to 174S prevented rescue, and rescue could be returned by combining 174S with 169I. When compared to rSA11 NSP4-wt, both rSA11 NSP4-R169I and rSA11 NSP4-R169I/A174S had a negligible but significant reduction in titre at specific time points. This study suggests that amino acid 174 of NSP4 may be essential in maintaining the VP6/NSP4 interaction required for DLP transport. Our results suggest that maintenance of specific polarities of amino acids at positions 169 and 174 may be required for the fitness of rotavirus field strains.

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来源期刊
Journal of General Virology
Journal of General Virology 医学-病毒学
CiteScore
7.70
自引率
2.60%
发文量
91
审稿时长
3 months
期刊介绍: JOURNAL OF GENERAL VIROLOGY (JGV), a journal of the Society for General Microbiology (SGM), publishes high-calibre research papers with high production standards, giving the journal a worldwide reputation for excellence and attracting an eminent audience.
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