GENETIC AND MOLECULAR ANALYSIS OF SYNAPTIC PLASTICITY

突触可塑性的遗传和分子分析

• 批准号: 6134469
• 负责人: Andrew Zelhof
• 金额: $ 3.92万
• 依托单位: UNIVERSITY OF CALIFORNIA, SAN DIEGO
• 依托单位国家: 美国
• 财政年份: 2000
• 资助国家: 美国
• 起止时间: 2000-08-02 至
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/6134469
• 关键词: Drosophilidae; chemoreceptors; larva; mutant; neural plasticity; olfactions; sensory signal detection

The long term goal of this proposal is to elucidate molecular mechanisms responsible for synaptic plasticity. It is well established that neurons rely on molecular recognition cues for guiding their neurites and in choosing their correct targets. While much has been learned about their recognition processes during the last few years, very little is known about the molecular details that govern the functional plasticity of synapses. Indeed, other than appreciating the importance of ion channels, intracellular messengers and kinases, we do not really understand how plasticity is orchestrated in vivo, and how activity or extracellular cues remodel synaptic arbors. This proposal aims to identify and define the molecular components required for activity-dependent structural remodeling of synapses. We hope these studies will help us outline specific molecular pathways, and begin a comprehensive dissection of synapses. We hope these studies will help us outline specific molecular pathways, and begin a comprehensive dissection of synaptic plasticity in vivo. We will focus our studies on the synapse between a Drosophila larval olfactory sensory neuron and its central target. As a first step towards a genetic screen, markers for the Drosophila larval olfactory system will be established. These markers will be used to mark selective neurons and their corresponding synaptic arborizations, and to carry out a genetic screen, markers for Drosophila larval olfactory sensory will be established.. These markers will be used to mark selective neurons and their corresponding synaptic arborizations, and to carry out a genetic screen for dominant gain-of-function and recessive loss-of-function mutations that alter specific synaptic arborization profiles. These screens will be combined with assays for activity-dependent structural changes in synaptic connections (e.g. olfactory cues). We hope this multifarious approach, bringing together genetic, molecular and physiological approaches will help elucidate basic principles of synapse biogenesis and plasticity.

该提案的长期目标是阐明负责突触可塑性的分子机制。众所周知，神经元依靠分子识别线索来引导其神经突并选择正确的目标。尽管在过去几年中人们对突触的识别过程有了很多了解，但对控制突触功能可塑性的分子细节却知之甚少。事实上，除了认识到离子通道、细胞内信使和激酶的重要性之外，我们并不真正了解体内可塑性是如何协调的，以及活动或细胞外线索如何重塑突触树干。该提案旨在识别和定义突触活动依赖性结构重塑所需的分子成分。我们希望这些研究将帮助我们概述特定的分子途径，并开始对突触进行全面的解剖。我们希望这些研究将帮助我们概述特定的分子途径，并开始对体内突触可塑性进行全面的剖析。我们将重点研究果蝇幼虫嗅觉感觉神经元与其中心目标之间的突触。作为遗传筛选的第一步，将建立果蝇幼虫嗅觉系统的标记。这些标记将用于标记选择性神经元及其相应的突触树枝，并进行遗传筛选，将建立果蝇幼虫嗅觉感觉标记。这些标记将用于标记选择性神经元及其相应的突触树枝，并对改变特定突触树枝的显性功能获得和隐性功能丧失突变进行遗传筛选 配置文件。这些筛选将与突触连接中活动依赖性结构变化（例如嗅觉线索）的检测相结合。我们希望这种将遗传、分子和生理学方法结合在一起的多样化方法将有助于阐明突触生物发生和可塑性的基本原理。