Control of cap independent translation by a viral 3' UTR

通过病毒 3 UTR 控制帽独立翻译

• 批准号: 6678471
• 负责人: Wyatt ALLEN MILLER
• 金额: $ 21.01万
• 依托单位: IOWA STATE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-07-01 至 2007-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6678471
• 关键词: RNA; RNA virus; binding sites; chemical structure function; gel mobility shift assay; genetic manipulation; genetic mapping; genetic regulation; genetic translation; host organism interaction; intermolecular interaction; nucleic acid sequence; nucleic acid structure; protein binding; protein biosynthesis; protein structure function; proteomics; ribosomes; translation factor; virus genetics; virus replication

DESCRIPTION (provided by applicant): Many RNA viruses usurp the host's protein synthesis (translation) machinery by bypassing the cellular translational control systems. The 5' cap and poly(A) tail on cellular mRNAs interact with translation factors to form a closed-loop mRNA structure in a regulated process necessary to recruit the ribosome and initiate translation. Many viral RNAs avoid this control step by lacking a 5' cap or poly(A) tail and instead harboring sequences in the untranslated regions (UTRs) that control translation by non-canonical means. Understanding how viruses do this could lead to development of antiviral agents specific to the unique viral translation mechanisms. This proposal focuses on the novel cap-independent translation element (TE) in the 3' UTR of barley yellow dwarf virus (BYDV) RNA that facilitates translation initiation at the 5' end. This research aims to determine how the TE (1) recruits translational machinery, and (2) communicates with the 5' end where initiation ensues. BYDV RNA forms the closed-loop structure by a novel means: direct base pairing between the 3' TE and the 5' UTR. This base pairing is necessary but insufficient to mediate translation in vivo. The first aim is to determine the tolerance of this closed-loop base pairing for sequence changes, and to distinguish the BYDV RNA sequences and structures that mimic 5' cap and poly(A) tail functions in vivo. The second aim is to identify the proteins that bind the TE, map their binding sites, and determine their roles. Preliminary evidence indicates that the TE may recruit the ribosome via factors that normally bind only to the 5' cap. The model to be tested is that factors and the ribosome are recruited to the 3' UTR and delivered to the 5' end by base pairing. The research will employ (and improve upon) established in vitro and in vivo translation assays, RNA replication assays, RNA structural analysis, RNA-protein binding and ribosome binding assays, proteomics, and structure-guided mutagenesis. This research on a model virus may contribute to means of controlling many human pathogens, including poliovirus and hepatitis C virus, that also employ cap-independent translation regulated by interactions between the UTRs. It also applies to nidoviruses and flaviviruses (e.g. Dengue, West Nile) that regulate gene expression and replication by long-distance RNA base pairing between UTRs. Finally, the research will provide fundamental insight on eukaryotic translation mechanisms.

描述（由申请人提供）：许多RNA病毒通过绕过细胞翻译控制系统而篡夺宿主的蛋白质合成（翻译）机制。细胞mRNA上的5'帽和poly（A）尾与翻译因子相互作用，以在募集核糖体和启动翻译所必需的调节过程中形成闭环mRNA结构。许多病毒RNA通过缺乏5'帽或聚腺苷酸尾而避免了该控制步骤，而是在非翻译区（UTR）中含有通过非规范方式控制翻译的序列。了解病毒如何做到这一点可能会导致开发针对独特病毒翻译机制的抗病毒剂。本研究的重点是在大麦黄矮病毒（BYDV）RNA的3'非翻译区中发现一个新的帽独立翻译元件（TE），该元件可促进5'末端的翻译起始。本研究旨在确定TE如何（1）招募翻译机器，以及（2）与起始启动的5'端进行通信。BYDV RNA通过一种新的方式形成闭环结构：3' TE和5' UTR之间的直接碱基配对。这种碱基配对是必要的，但不足以介导体内翻译。第一个目的是确定这种闭环碱基配对对序列变化的耐受性，并区分BYDV RNA序列和模拟体内5'帽和poly（A）尾功能的结构。第二个目的是确定结合TE的蛋白质，绘制其结合位点，并确定其作用。初步证据表明，TE可能通过通常仅结合5'帽的因子募集核糖体。待测试的模型是因子和核糖体被募集到3' UTR并通过碱基配对递送到5'末端。该研究将采用（并改进）已建立的体外和体内翻译测定，RNA复制测定，RNA结构分析，RNA-蛋白质结合和核糖体结合测定，蛋白质组学和结构指导诱变。对模型病毒的这项研究可能有助于控制许多人类病原体的方法，包括脊髓灰质炎病毒和丙型肝炎病毒，这些病原体也采用由UTR之间的相互作用调节的帽非依赖性翻译。它也适用于通过UTR之间的长距离RNA碱基配对调节基因表达和复制的巢病毒和黄病毒（例如登革热、西尼罗河病毒）。最后，该研究将为真核生物翻译机制提供基础性的见解。