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REGULATED MRNA TRANSLATION IN DROSOPHILA BODY PATTERNING

果蝇身体模式中的 mRNA 翻译调控

基本信息

批准号：
7454177
负责人：
Paul M. Macdonald
金额：
$ 26.56万
依托单位：
UNIVERSITY OF TEXAS AT AUSTIN
依托单位国家：
美国
项目类别：
财政年份：
1995
资助国家：
美国
起止时间：
1995-09-30 至 2012-06-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7454177
关键词：
Animals Binding Binding Sites Biochemical Biological Assay Body Patterning Cells Data Development Dimerization Disease Drosophila genus Embryo Embryonic Development Funding Future Gene Expression Genes Genome Goals Human Marshal Mediating Messenger RNA MicroRNAs Modeling Molecular Conformation Mothers Nervous System Physiology Oocytes Pathway interactions Pattern Polyadenylation Polyribosomes Positioning Attribute Protein Binding Proteins RNA Range Regulation Relative (related person)Repression Research Personnel Role Shapes Specific qualifier value Staging System Testing Thinking Time Translation Initiation Translational Activation Translational Regulation Translational Repression Translations Untranslated Regions Work cis acting element egg in vivo novel prevent programs protein expression protein protein interaction selective expression zygote

项目摘要

DESCRIPTION (provided by applicant): Proper control of gene expression underlies the formation and function of all cells. Regulation at the level of translation, once thought to be limited in its scope, has emerged as an important feature in a wide range of settings, from the earliest stages of development to the function of the nervous system. Recent advances that reveal the widespread expression of microRNAs, which control a novel form of translational control, further expand the fraction of mRNAs whose translation is regulated. In Drosophila, translational control and mRNA localization act coordinately in deployment of body patterning determinants at particular positions in the oocyte and embryo. One determinant is encoded by the oskar gene, and its restriction to the posterior pole of the oocyte is essential. The controls used to achieve that distribution include two forms of translational repression (one strikingly similar to microRNA-dependent repression), mRNA localization, and two or more forms of translational activation. A protein that binds to oskar mRNA, Bruno, mediates one form of repression as well as one form of activation. Our long term goal is to understand each of these mechanisms and how they are coordinated. The immediate goals focus on Bruno, and how it can function as a represser when bound to one region of the oskar mRNA 3' UTR, and as an activator when bound to another region of the 3' UTR. The two Bruno-binding regions of the oskar mRNA are organized differently, and the RNA of one region can inhibit a Bruno/protein interaction (dimerization) while the other cannot. We hypothesize that the differences in the binding sites alter the conformation of bound Bruno, or limit the manner in which Bruno can bind. The different conformations of bound Bruno would then promote or allow different options for Bruno/protein interactions (Bruno/Cup for repression, Bru/? for activation), and thus specify repression or activation. We will test this model, which best fits the current data, as well as other models. We will also test the model that Bruno dependent activation involves cytoplasmic polyadenylation. Many diseases result from inappropriate gene expression. Our work, on genes such as Bruno that have close relatives in humans, will advance understanding of the basic mechanisms that control gene expression.

描述（由申请人提供）：适当控制基因表达是所有细胞形成和功能的基础。翻译水平的调节，曾经被认为在其范围内是有限的，已经成为广泛设置的一个重要特征，从最早的发展阶段到神经系统的功能。最近的研究进展揭示了microRNAs的广泛表达，microRNAs控制着一种新的翻译控制形式，进一步扩大了mrna翻译受调节的比例。