SR蛋白剪接因子与劳氏肉瘤病毒剪接元件负调控因子相互作用。

SR protein splicing factors interact with the Rous sarcoma virus negative regulator of splicing element.

作者信息

McNally L M, McNally M T

机构信息

Department of Microbiology, Medical College of Wisconsin, Milwaukee 53226, USA.

出版信息

J Virol. 1996 Feb;70(2):1163-72. doi: 10.1128/JVI.70.2.1163-1172.1996.

DOI:10.1128/JVI.70.2.1163-1172.1996

PMID:8551577

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC189925/

Abstract

Retroviral replication requires that a portion of the primary transcripts generated from proviral DNA be spliced to serve as mRNA for the envelope protein and in Rous sarcoma virus as src mRNA. However, a substantial amount of full-length RNA must be maintained in an unspliced form, as the unspliced RNA serves both as mRNA for structural proteins and virion-associated enzymatic proteins and as genomic RNA for progeny virions. The extent of viral RNA splicing must be finely controlled, since only a narrow range in the ratio of unspliced RNA to spliced RNA is tolerated for optimal replication. A number of cis-acting sequences within the RNA of Rous sarcoma virus play a role in preserving a large pool of unspliced RNA. One such sequence, the negative regulator of splicing (NRS), is of interest because it blocks splicing but is not located near any of the splice junctions. To better understand how this novel element blocks splicing at a distance, we set out to identify host cell factors that interact specifically with this inhibitory sequence. In this study, proteins from nuclear extracts with molecular masses of 26, 36, 44, and 55 kDa were shown by UV cross-linking assays to bind the NRS preferentially. One of them, p55, was also detected in a specific complex with SR protein electrophoretic mobility shift assay. All but p55 have biochemical properties consistent with SR protein splicing factors, and some, but not all, of the total SR proteins purified from HeLa cells cross-link specifically to the NRS. The strongest cross-linking SR protein is SRp30a/b, which is composed of the splicing factors SF2/ASF and SC35. The NRS specifically binds bacterially expressed SF2/ASF, whereas nonfunctional mutants do not. Data indicating that the 36-kDa protein which cross-links in nuclear extracts is SF2/ASF are presented. The data indicate that factors normally required for RNA splicing may be exploited by retroviruses to block splicing.

摘要

逆转录病毒的复制要求从原病毒DNA产生的部分初级转录本进行剪接，以作为包膜蛋白的mRNA，在劳氏肉瘤病毒中则作为src mRNA。然而，大量的全长RNA必须保持未剪接的形式，因为未剪接的RNA既作为结构蛋白和病毒体相关酶蛋白的mRNA，又作为子代病毒体的基因组RNA。病毒RNA剪接的程度必须受到精确控制，因为只有在未剪接RNA与剪接RNA的比例处于很窄的范围内时，才能实现最佳复制。劳氏肉瘤病毒RNA中的一些顺式作用序列在保留大量未剪接RNA方面发挥作用。其中一个这样的序列，即剪接负调控因子（NRS），很受关注，因为它能阻断剪接，但并不位于任何剪接位点附近。为了更好地理解这个新元件如何在远距离阻断剪接，我们着手鉴定与这个抑制序列特异性相互作用的宿主细胞因子。在这项研究中，通过紫外线交联试验表明，来自核提取物的分子量为26、36、44和55 kDa的蛋白质优先结合NRS。其中之一，p55，在与SR蛋白的电泳迁移率变动分析的特异性复合物中也被检测到。除了p55之外，其他所有蛋白质都具有与SR蛋白剪接因子一致的生化特性，并且从HeLa细胞中纯化的部分但不是全部的总SR蛋白能与NRS特异性交联。交联最强的SR蛋白是SRp30a/b，它由剪接因子SF2/ASF和SC35组成。NRS特异性结合细菌表达的SF2/ASF，而无功能的突变体则不能。本文提供的数据表明，在核提取物中发生交联的36 kDa蛋白质是SF2/ASF。这些数据表明，逆转录病毒可能利用RNA剪接通常所需的因子来阻断剪接。

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Rev and the fate of pre-mRNA in the nucleus: implications for the regulation of RNA processing in eukaryotes.Rev与细胞核内前体mRNA的命运：对真核生物RNA加工调控的影响

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