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聚合酶发生滑动,并且PIPO存在。

The polymerase slips and PIPO exists.

作者信息

White K Andrew

机构信息

Department of Biology, York University, Toronto, ON, Canada.

出版信息

EMBO Rep. 2015 Aug;16(8):885-6. doi: 10.15252/embr.201540871. Epub 2015 Jul 9.

DOI:10.15252/embr.201540871
PMID:26160653
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4552478/
Abstract

Plant viruses that contain plus-sensed single-stranded RNA genomes are highly abundant in nature. As the equivalents of large mRNAs, these viral genomes utilize a wide variety of gene expression strategies for the production of their encoded proteins. The potyviruses, which are among the most agriculturally important members in this category, contain a single large open reading frame (ORF) coding for a polyprotein that is processed into functional units. For many years, the products derived from the full-length polyprotein were thought to be the only functional viral proteins. However, this notion was dispelled when an additional essential viral ORF, PIPO, was discovered encoded in an alternative reading frame. Since then, the PIPO protein—P3N-PIPO, which mediates virus movement in plants—has been intensively studied, but its mode of expression remained elusive until now. Two articles, one in this issue of , now report that slippage of the viral polymerase during viral genome replication is responsible for shifting PIPO into a translated reading frame, thereby allowing for production of P3N-PIPO ,. This mechanism of gene expression represents a novel strategy for plant viruses.

摘要

含有正义单链RNA基因组的植物病毒在自然界中极为丰富。作为大型mRNA的等价物,这些病毒基因组利用多种基因表达策略来产生其编码的蛋白质。马铃薯Y病毒属病毒是这一类中对农业最为重要的成员之一,它含有一个单一的大开放阅读框(ORF),编码一种多聚蛋白,该多聚蛋白被加工成功能单元。多年来,人们一直认为源自全长多聚蛋白的产物是唯一具有功能的病毒蛋白。然而,当在一个替代阅读框中发现一个额外的必需病毒ORF(PIPO)时,这一观念被推翻。从那时起,介导病毒在植物中移动的PIPO蛋白——P3N-PIPO就受到了深入研究,但直到现在其表达模式仍不清楚。本期的两篇文章现在报道,病毒基因组复制过程中病毒聚合酶的滑移负责将PIPO转移到一个可翻译的阅读框中,从而使得P3N-PIPO得以产生。这种基因表达机制代表了植物病毒的一种新策略。

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