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In vivo optical imaging of experience-induced olfactory bulb glomerular plasticit

经验诱导的嗅球肾小球可塑性的体内光学成像

基本信息

批准号：
8014952
负责人：
MAX L FLETCHER
金额：
$ 14.18万
依托单位：
UNIVERSITY OF TENNESSEE HEALTH SCI CTR
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-02-02 至 2013-01-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8014952
关键词：
Address Adult Affect Aldehydes Alzheimer&apos s Disease Animals Behavior Behavioral Biological Models Calcium Cells Code Data Diagnosis Disease Dorsal Food Functional disorder Goals Grant Health Human Image Individual Learning Life Mammals Maps Memory Mus Neocortex Neuraxis Neurons Odors Olfactory Learning Olfactory Pathways Output Parkinson Disease Pathway interactions Pattern Perception Play Process Reproduction Rodent Role Schizophrenia Sensory Sensory Process Series Shapes Site Smell Perception Source Staging Stimulus Surface Synapses System Testing Time Training Transgenic Mice aversive conditioning base calcium indicator classical conditioning conditioning experience imaging modality imprint in vivo interest mouse model nervous system disorder neural circuit novel olfactory bulb optical imaging postsynaptic receptive field receptor relating to nervous system response sensor sensory cortex sensory stimulus sensory system social

项目摘要

DESCRIPTION (provided by applicant): The long-term goal of this project is to understand how learning can influence olfactory odorant representations at the first level of processing within the olfactory bulb. While the mammalian olfactory system has been shown to have a remarkable capability for undergoing experience-dependent plasticity, how such odor memories are imprinted in the adult olfactory neural circuit remains unclear. Although this process most likely involves changes at multiple stages in the olfactory pathway, one interesting site for plasticity is the olfactory glomerular layer. Within this layer, the anatomical organization of receptor neuron input allows odorant information to be transformed into an odorant-specific topographical map of glomerular activity. This activity pattern can be visualized in vivo using a newly-developed transgenic mouse with a GFP-based calcium indicator (G-CaMP2) expressed exclusively in olfactory bulb output neurons immediately postsynaptic to receptor input. Unlike previous imaging methods, this mouse allows us to observed purely postsynaptic odor maps in the glomerular layer for the first time. Using this mouse model we can directly test the hypothesis that olfactory learning significantly alters olfactory bulb postsynaptic glomerular odorant representations for the trained odorant. This will be accomplished by comparing odorant-evoked glomerular activity patterns in the same animal before and after associative conditioning. Preliminary data suggests that conditioning with a given odorant significantly alters glomerular responses to that odorant following training. Based on this, we plan to extend our findings by testing the hypothesis that these changes will serve to reduce the representational overlap between the trained odorant and similar odorants. Together, these studies will have a significant impact on our understanding of the neural basis of odor coding and role plasticity plays in shaping neural responses to sensory stimuli. PUBLIC HEALTH RELEVANCE: The sense of smell plays an important role in our daily life. Olfaction dysfunction is often times an early indicator of several major neurological diseases in humans including Alzheimer's disease, Parkinson's disease, and schizophrenia. The general goal of this grant is to understand the neural basis of olfactory processing which could help in the diagnosis and treatment of these diseases.

描述（由申请人提供）：本项目的长期目标是了解学习如何影响嗅球内第一级处理的嗅觉气味表征。虽然哺乳动物的嗅觉系统已被证明具有经历经验依赖性可塑性的显着能力，但这种气味记忆如何在成年人的嗅觉神经回路中留下印记仍不清楚。虽然这一过程很可能涉及嗅觉通路多个阶段的变化，但一个有趣的可塑性位点是嗅球层。在这一层内，受体神经元输入的解剖组织允许气味信息被转化为肾小球活动的气味特异性地形图。这种活动模式可以在体内可视化使用新开发的转基因小鼠与GFP为基础的钙指示剂（G-CaMP 2），专门表达在嗅球输出神经元立即突触后受体输入。与以前的成像方法不同，这只小鼠使我们能够首次观察到肾小球层中纯粹的突触后气味图。使用这个小鼠模型，我们可以直接测试这样的假设：嗅觉学习显着改变了嗅球突触后小球对训练气味的气味表征。这将通过比较气味诱发的肾小球活动模式在同一动物之前和之后的联想条件反射。初步数据表明，条件反射与给定的气味显着改变肾小球反应的气味训练后。在此基础上，我们计划通过测试这些变化将有助于减少训练气味和类似气味之间的代表性重叠的假设来扩展我们的发现。总之，这些研究将对我们理解气味编码的神经基础和可塑性在塑造神经对感官刺激的反应中所起的作用产生重大影响。公共卫生相关性：嗅觉在我们的日常生活中起着重要的作用。嗅觉功能障碍通常是人类几种主要神经系统疾病的早期指标，包括阿尔茨海默病，帕金森病和精神分裂症。这项资助的总体目标是了解嗅觉处理的神经基础，这有助于诊断和治疗这些疾病。