Mechanism of Protein Synthesis and Translational Control

蛋白质合成与翻译控制机制

• 批准号: 10581388
• 负责人: SIMPSON JOSEPH
• 金额: $ 12.43万
• 依托单位: UNIVERSITY OF CALIFORNIA, SAN DIEGO
• 依托单位国家: 美国
• 财政年份: 2021
• 资助国家: 美国
• 起止时间: 2021-06-01 至 2026-05-31
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10581388
• 关键词: American; Antiviral Agents; Binding; Biochemical; Brain; Cells; Cellular Stress; Cessation of life; Childhood; Code; Complex; Conserved Sequence; Data; Development; Disease; Drug Targeting; Eukaryotic Initiation Factor-4E; FMR1; FXR1 gene; FXR2 gene; Fragile X Syndrome; Gene Silencing; Genes; Goals; In Vitro; Influenza A virus; Intellectual functioning disability; Knowledge; Mammals; Messenger RNA; Molecular; Patients; Persons; Pharmaceutical Preparations; Poly(A)-Binding Proteins; Protein Biosynthesis; Proteins; Public Health; RNA-Binding Proteins; Regulation; Research; Resistance; Seizures; System; Techniques; Translation Initiation; Translation Process; Translations; Untranslated Regions; Viral; Virus Diseases; autistic behaviour; biophysical techniques; influenza infection; insight; mRNA Expression; paralogous gene; programs; recruit

Project Summary Our research program focuses on the mechanism of eukaryotic protein synthesis and translational control. The two projects we are currently studying are: (1) the mechanism of translational control by the fragile X mental retardation protein (FMRP), and (2) the mechanism of translation initiation on influenza A virus (IAV) mRNAs. Fragile X syndrome is a disease that afflicts about 100,000 Americans and about 3 million people worldwide, resulting in intellectual disability, childhood seizures, and autistic behavior in the patients. The disease is caused by the transcriptional silencing of the fragile X mental retardation 1 gene (FMR1). FMR1 gene codes for an RNA-binding protein, FMRP, which is highly expressed in the brain and is essential for the normal development of the brain. Mammals have two autosomal paralogs of FMRP designated as fragile X-related 1 and 2 (FXR1 and FXR2) proteins. FMRP, FXR1, and FXR2 have been implicated in regulating the translation of several mRNAs. However, the precise mechanism by which these proteins regulate the expression of these mRNAs is unknown. The goal of the first project is to understand the molecular mechanism underlying the regulation of protein synthesis by FMRP, FXR1, and FXR2. We will use a robust in vitro translation system, biochemical techniques, and quantitative biophysical methods to significantly advance our understanding of the molecular mechanism used by FMRP, FXR1, and FXR2 to regulate protein synthesis. Results of these studies will provide useful insights in identifying potential drug targets to treat fragile X syndrome. The goal of the second project is to investigate the mechanism of translation initiation by IAV mRNAs. IAV is responsible for several thousand deaths annually and is a severe threat to global public health. We have new data that indicate that IAV mRNAs may use a non-canonical mechanism of translation initiation. Our studies show that poly A binding protein 1 (PABP1) binds to the highly conserved sequences present in the 5’-UTR of IAV mRNAs. Additionally, we show that the translation of the IAV mRNA is more resistant to the inactivation of eukaryotic initiation factor 4E (eIF4E) compared to a control mRNA. We hypothesize that the recruitment of PABP1 to the viral 5’-UTRs tethers eIF4G and promotes the assembly of the translation initiation complex in an eIF4E-independent manner. This may favor the translation of IAV mRNAs under cellular stress conditions in the cell, which is known to reduce the activity of eIF4E. We will determine whether the binding of PABP1 to the 5’- UTR of IAV mRNAs is essential for translation initiation and the viral cycle using in vitro techniques and cellular IAV infection studies. Our research will lead to fundamental new knowledge about the process of translation initiation on IAV mRNAs, which could help in the development of new antiviral drugs.

项目摘要 我们的研究项目主要集中在真核生物蛋白质合成和翻译的机制， 控制我们目前正在研究的两个项目是：（1）脆性体的翻译控制机制 （2）甲型流感病毒（IAV）的翻译起始机制 mRNA。脆性X染色体综合征是一种困扰着大约10万美国人和大约300万人的疾病 在世界范围内，导致智力残疾，儿童癫痫发作和自闭症行为的患者。的 这种疾病是由脆性X智力低下1基因（FMR 1）的转录沉默引起的。fmr 1基因 编码一种RNA结合蛋白，FMRP，它在大脑中高度表达，对正常的 大脑的发展。哺乳动物有两个FMRP的常染色体旁系同源物，称为脆性X相关1 和2种（FXR 1和FXR 2）蛋白。FMRP、FXR 1和FXR 2参与调节翻译， 几种mRNA。然而，这些蛋白质调节这些蛋白质表达的精确机制是不确定的。 mRNA未知。第一个项目的目标是了解 通过FMRP、FXR 1和FXR 2调节蛋白质合成。我们将使用一个强大的体外翻译系统， 生物化学技术和定量生物物理学方法，以显着推进我们对 FMRP、FXR 1和FXR 2用于调节蛋白质合成的分子机制。这些研究结果 将为确定治疗脆性X综合征的潜在药物靶点提供有用的见解。 第二个项目的目标是研究IAV mRNA翻译起始的机制。 IAV每年造成数千人死亡，对全球公共卫生构成严重威胁。我们有 新的数据表明，IAV mRNA可能使用非经典的翻译起始机制。我们的研究 显示多聚腺苷酸结合蛋白1（PABP 1）结合存在于 IAV mRNA。此外，我们还发现IAV mRNA的翻译更能抵抗病毒的失活。 真核生物起始因子4 E（eIF 4 E）与对照mRNA相比。我们假设， PABP 1与病毒5 '-UTR的结合系住eIF 4G，并促进翻译起始复合物在细胞内的组装。 eIF 4 E独立的方式。这可能有利于IAV mRNA在细胞应激条件下的翻译。 细胞，已知其降低eIF 4 E的活性。我们将确定PABP 1与5 '- IAV mRNA的UTR对于翻译起始和使用体外技术和细胞内技术的病毒周期是必需的。 IAV感染研究。我们的研究将导致对翻译过程的基本新知识 这可能有助于开发新的抗病毒药物。