Examining the neural circuit for an instinctive olfactory-induced behavior in lar

检查 lar 中本能嗅觉诱发行为的神经回路

• 批准号: 8680205
• 负责人: Scott T. Laughlin
• 金额: $ 15.8万
• 依托单位: STATE UNIVERSITY NEW YORK STONY BROOK
• 依托单位国家: 美国
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-07-01 至 2016-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8680205
• 关键词: Adult; Afferent Neurons; Aggressive behavior; Anatomy; Animal Model; Anxiety; Area; Attenuated; Axon; Behavior; Behavioral; Biological Assay; Biological Models; Brain; Chemicals; Chondroitin; Chronic; Collection; Data; Dendrites; Environment; Esthesia; Exhibits; Fishes; Foundations; Fright; Future; Goals; Human; Human Biology; Hypoxanthines; Image; Imagery; Individual; Instinct; Larva; Lead; Lesion; Mediating; Mental Health; Modeling; Molecular; Molecular Structure; Mus; Nature; Nervous system structure; Neural Pathways; Neurobiology; Neurons; Neuropil; Nose; Odorant Receptors; Organic solvent product; Perception; Pheromone; Positioning Attribute; Process; Proteins; Quality of life; Receptor Signaling; Research; Research Design; Rodent Model; Sensory; Signal Pathway; Signal Transduction; Skin; Smell Perception; Solid; Stereotyping; Stress; Structure; System; Techniques; Testing; Time; Zebrafish; cell type; innovation; insight; neural circuit; neuromechanism; novel; olfactory bulb; olfactory receptor; olfactory stimulus; optical imaging; public health relevance; receptor; receptor binding; relating to nervous system; research study; response; solvent extraction; tool; urinary

DESCRIPTION (provided by applicant): Olfaction-the sense of smell-is the major means though which we sense our chemical surroundings, and as such, it has a significant impact on quality of life. One of the overarching goals in the field of olfactory neurobiology is to understad the neural pathways that connect an olfactory stimulus, its representation in the brain as a percept, and the circuits that drive downstream behaviors. Perhaps the greatest obstacle to understanding these neural pathways is the complexity and physical size of the nervous system. For example, mice, which have numerous olfactory-guided behaviors, have ~1000 different odorant receptors, 5-10 million olfactory sensory neurons, and 1800 distinct collections of axons and dendrites, called glomeruli, in the olfactory bulb, the brain area specialized in processing the initial steps of olfaction. In this proposal, we describe a strategy to study the neural circuiry underlying olfaction in a system that is at least 10 times simpler than mice, the zebrafish larvae. The key innovation of this strategy is our use of a recently identified, innate olfactory-guided behavior to study olfactory circuits. Although five-day-old zebrafish exhibit several innate behaviors, until recently there were no known robust olfactory-guided behaviors in zebrafish larvae. Here we demonstrate that zebrafish larvae exhibit a stereotyped, olfactory-guided fear behavior in response to components in an organic solvent extraction of zebrafish skin. Ultimately, using this behavior as a guide, we will be able to connect the sensation of specific molecular structures with the types of olfactory receptors they bind, the types of olfactory sensory neurons they activate, and the neural circuit they excite in order to generate behavior. In Specific Aim 1, we describe experiments to identify which of the three olfactory sensory neuron types is stimulated by the behaviorally active odorants. These results will enable future experiments that allow us to narrow the search for the relevant receptors and signaling pathways underlying this olfactory-guided behavior. In Specific Aim 2, we describe two separate but complementary strategies to identify the anatomy of the olfactory neural circuit at the first olfactory-processing step in the brain, the glomeruli of the olfactory bulb. In Specific Aim 2.1, w identify which glomeruli are a part of the neural circuit underlying the olfactory behavior by imaging their neural activity in response to sensory reception of purified, behaviorally active molecules. In Specific Aim 2.2, we identify the relevant glomeruli by ablating them and looking for a diminished behavioral response. The results of these experiments will increase our understanding of the neural circuits underlying a innate, olfactory-guided behavior, and will provide a solid foundation for an R01 application to support future studies on the elucidation of neural circuits mediating innate behaviors.

描述（由申请人提供）：嗅觉-嗅觉-是我们感知化学环境的主要手段，因此，它对生活质量有重大影响。嗅觉神经生物学领域的首要目标之一是了解连接嗅觉刺激的神经通路，其在大脑中的代表性，以及驱动下游行为的电路。也许理解这些神经通路的最大障碍是神经系统的复杂性和物理尺寸。例如，具有许多嗅觉引导行为的小鼠，在嗅球中具有约1000种不同的气味受体，500 - 1000万个嗅觉感觉神经元和1800个不同的轴突和树突集合，称为肾小球，嗅球是专门处理嗅觉初始步骤的大脑区域。在这个提议中，我们描述了一种策略，研究系统中嗅觉的神经回路，该系统至少比小鼠（斑马鱼幼虫）简单10倍。 这一策略的关键创新是我们使用最近发现的先天嗅觉引导行为来研究嗅觉回路。虽然5天大的斑马鱼表现出几种先天行为，但直到最近，斑马鱼幼虫中还没有已知的强大的嗅觉引导行为。在这里，我们表明，斑马鱼幼虫表现出刻板的，嗅觉引导的恐惧行为，响应于斑马鱼皮肤的有机溶剂提取物中的成分。最终，以这种行为为指导，我们将能够将特定分子结构的感觉与它们所结合的嗅觉受体类型、它们所激活的嗅觉感觉神经元类型以及它们所激发的神经回路联系起来，以产生行为。在具体目标1中，我们描述了实验，以确定哪三种嗅觉感觉神经元类型是由行为活性气味刺激。这些结果将使未来的实验，使我们能够缩小搜索相关受体和信号通路的基础上，这种嗅觉引导的行为。在具体目标2中，我们描述了两个独立但互补的策略，以确定在大脑中的第一个嗅觉处理步骤，嗅球的肾小球的嗅觉神经回路的解剖结构。在具体目标2.1中，我们通过成像肾小球对纯化的行为活性分子的感觉接收的神经活动，确定哪些肾小球是嗅觉行为背后的神经回路的一部分。在具体目标2.2中，我们通过消融肾小球并寻找减弱的行为反应来识别相关肾小球。这些实验的结果将增加我们对先天嗅觉引导行为背后的神经回路的理解，并将为R 01应用提供坚实的基础，以支持未来关于阐明神经回路介导先天行为的研究。