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DROSOPHILA NEURONAL TEMPORAL IDENTITY

果蝇神经元时间特性

基本信息

批准号：
8287137
负责人：
TZUMIN LEE
金额：
$ 36.64万
依托单位：
UNIV OF MASSACHUSETTS MED SCH WORCESTER
依托单位国家：
美国
项目类别：
财政年份：
2008
资助国家：
美国
起止时间：
2008-08-01 至 2013-06-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8287137
关键词：
5&apos Untranslated Regions Address Adult Back Behavior Biological Models Birth Order Brain Brain Stem Cells Characteristics Cis-Acting Sequence Clinical Color Complex Degenerative Disorder Development Developmental Process Drosophila genus Employee Strikes Exhibits Future Gelshift Analysis Gene Silencing Generations Genes Genetic Genetic Screening Goals Health Injury Intervention Knowledge Lateral Lobe Mediating Messenger RNA Mitotic Molecular Morphogenesis Morphology Mushroom Bodies Neurons Neurosciences Nuclear Protein Organism Pathway interactions Pattern Population Process Property Proteins RNA Interference Regulatory Element Research Role Specific qualifier value Staging Stem cells System Testing Time Trans-Activators Translations Zinc Fingers cell fate specification crosslink design developmental disease insight loss of function neuroblast neurogenesis novel relating to nervous system research study tool trait

项目摘要

DESCRIPTION (provided by applicant): To unravel how the astonishing diversity of neurons is derived through birth order/timing-dependent cell fate specification, we propose to use sophisticated genetic tools in a relatively simple organism, the fruit fly Drosophila, to study the mechanisms of neuronal temporal identity. From a genetic mosaic screen, we have identified the Drosophila Chinmo BTB-zinc finger protein, and in particular its gradients through neurogenesis, as a novel mechanism conferring neuronal temporal identity. We have further demonstrated that the establishment of the Chinmo gradient involves the differential translation of chinmo messages carrying a 1.7kb-long 5'UTR. In this proposal, we will (1) examine the generality of Chinmo function in specifying neuronal temporal identity, (2) investigate the chinmo 5'UTR-dependent translational control for tracing back the origin for Chinmo-governed neuronal temporal cell fate specifications, and (3) screen for additional genes that may act within the Chinmo pathway or operate independently to control neuronal temporal identity. This study, including thorough analysis of Chinmo function and systematical identification of temporal identity genes, promises to provide major insights into the mechanisms governing birth order/timing-dependent neuronal diversification, a crucial developmental process in the brain. PUBLIC HEALTH RELEVANCE: The brain is composed of a monumental number of different types of neurons. These neurons interact with each other forming the complex brain circuits that underlie behavior and the coordination of the vital functions of the body. Congenital and developmental disorders that interfere with the formation of neuronal diversity have drastic consequences for brain function. Further, knowledge about the stem cells that in the brain give rise to this diversity may provide powerful clinical approaches for interventions during degenerative disorders or after injury. The goal of this project is to understand how brain stem cells give rise to neuronal diversity according to the order in which neurons are born (temporal identity). To address this question we are using a powerful model system, the fruit fly Drosophila, in which the genes controlling temporal identity can be isolated in an efficient manner. Our studies in this system have isolated a gene, called chinmo (chronologically inappropriate morphogenesis) with central roles in this process. In this project we will elucidate the mechanisms of Chinmo function by (a) determining if it is a universal temporal identity gene, or whether there are other genes that also can fulfill this function, (b) determining the mechanisms by which Chinmo functions, and (c) searching for other cell identity genes that may function with Chinmo, or in a Chinmo-independent fashion to confer temporal identity. We expect that the studies proposed will have a fundamental impact in our understanding of how neuronal diversity is generated, how this neuronal diversity is encoded in stem cells, and how these stem cells can be manipulated in order to generate particular neuron populations.

描述（由申请人提供）：为了揭示神经元的惊人多样性是如何通过出生顺序/时间依赖的细胞命运说明书衍生出来的，我们建议在果蝇这种相对简单的生物中使用复杂的遗传工具来研究神经元时间身份的机制。通过基因马赛克筛选，我们已经鉴定出了Chinmo果蝇btb -锌指蛋白，特别是其通过神经发生的梯度，作为一种赋予神经元时间身份的新机制。我们进一步证明了Chinmo梯度的建立涉及携带1.7kb长5'UTR的Chinmo信息的差分翻译。在这一建议中，我们将(1)检查Chinmo在指定神经元颞叶身份方面的功能的普遍性，(2)研究Chinmo 5' utr依赖的翻译控制，以追溯Chinmo控制的神经元颞叶细胞命运规范的起源，以及(3)筛选可能在Chinmo途径中起作用或独立作用的其他基因，以控制神经元的颞叶身份。这项研究，包括对Chinmo功能的深入分析和对时间身份基因的系统鉴定，有望为控制出生顺序/时间依赖性神经元多样化的机制提供重要的见解，这是大脑中一个重要的发育过程。