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埃博拉病毒VP30介导的转录受RNA二级结构形成的调控。

Ebola virus VP30-mediated transcription is regulated by RNA secondary structure formation.

作者信息

Weik Michael, Modrof Jens, Klenk Hans-Dieter, Becker Stephan, Mühlberger Elke

机构信息

Institut für Virologie der Philipps-Universität Marburg, 35037 Marburg, Germany.

出版信息

J Virol. 2002 Sep;76(17):8532-9. doi: 10.1128/jvi.76.17.8532-8539.2002.

DOI:10.1128/jvi.76.17.8532-8539.2002
PMID:12163572
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC136988/
Abstract

The nucleocapsid protein VP30 of Ebola virus (EBOV), a member of the Filovirus family, is known to act as a transcription activator. By using a reconstituted minigenome system, the role of VP30 during transcription was investigated. We could show that VP30-mediated transcription activation is dependent on formation of a stem-loop structure at the first gene start site. Destruction of this secondary structure led to VP30-independent transcription. Analysis of the transcription products of bicistronic minigenomes with and without the ability to form the secondary structure at the first transcription start signal revealed that transcription initiation at the first gene start site is a prerequisite for transcription of the second gene, independent of the presence of VP30. When the transcription start signal of the second gene was exchanged with the transcription start signal of the first gene, transcription of the second gene also was regulated by VP30, indicating that the stem-loop structure of the first transcription start site acts autonomously and independently of its localization on the RNA genome. Our results suggest that VP30 regulates a very early step of EBOV transcription, most likely by inhibiting pausing of the transcription complex at the RNA structure of the first transcription start site.

摘要

埃博拉病毒(EBOV)是丝状病毒科的成员,其核衣壳蛋白VP30已知可作为转录激活因子。通过使用重组的微型基因组系统,研究了VP30在转录过程中的作用。我们可以证明,VP30介导的转录激活依赖于在第一个基因起始位点形成茎环结构。破坏这种二级结构会导致不依赖VP30的转录。对具有和不具有在第一个转录起始信号处形成二级结构能力的双顺反子微型基因组的转录产物分析表明,在第一个基因起始位点的转录起始是第二个基因转录的前提条件,与VP30的存在无关。当第二个基因的转录起始信号与第一个基因的转录起始信号交换时,第二个基因的转录也受VP30调控,这表明第一个转录起始位点的茎环结构自主发挥作用,与其在RNA基因组上的定位无关。我们的结果表明,VP30调节EBOV转录的一个非常早期的步骤,很可能是通过抑制转录复合物在第一个转录起始位点的RNA结构处的暂停来实现的。

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