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Molecular and Cellular Mechanisms of a Neuronal Network that Regulates Olfactory

调节嗅觉的神经网络的分子和细胞机制

基本信息

批准号：
8298625
负责人：
Yun Zhang
金额：
$ 40.25万
依托单位：
HARVARD UNIVERSITY
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：
2009-08-15 至 2014-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8298625
关键词：
Ablation Address Afferent Neurons Animal Model Animals Aversive Stimulus Basic Science Behavioral Behavioral Assay Biochemical Biological Neural Networks Caenorhabditis elegans Calcium Calmodulin Cues Defect Environment Food G alpha q Protein G-Protein Signaling Pathway Genetic Genetic Models Goals Health Image Individual Infection Ingestion Interneurons Laser Surgery Learning Life Link Maps Memory Molecular Molecular Genetics Motor output Nervous system structure Neurologic Neuronal Plasticity Neurons Olfactory Learning Pathway interactions Phosphotransferases Physiological Post-Transcriptional Regulation Process Property Psyche structure Quality of life Research Role Sensory Serotonin Serotonin Production Shapes Signal Pathway Signal Transduction Smell Perception Source Stress Testing Time Training Uncertainty Work base cellular pathology disability enzyme biosynthesis experience imaging modality insight interest molecular imaging molecular pathology nervous system disorder neural circuit operation pathogen pathogenic bacteria response tool

项目摘要

DESCRIPTION (provided by applicant): We are interested to understand how individuals communicate with environment by olfaction and, particularly, how olfactory responses are shaped and modified by experience and environmental cues. To this end, we use a genetic model organism Caenorhabditis elegans and a new form of olfactory plasticity in this animal model to ask the following questions: What is the functional organization of the neuronal circuit underlying olfactory learning? How does experience generate modulatory cues to modify olfaction? How does the intrinsic property of the olfactory circuitry change in response to experience to generate olfactory learning? We previously showed that C. elegans learns to avoid the smell of pathogenic bacteria after ingestion of the pathogens. Serotonin signaling from a pair of serotonergic neurons ADF and an olfactory circuit are essential to direct this learning process. The physiological stress of infection enhances ADF serotonin signals through CaMKII and a Gq pathway; and the strengthened signaling promotes learning through a serotonin-gated channel in several interneurons. An olfactory neural circuit downstream of two pairs of sensory neurons is required for this learning to occur. We hypothesize that the enhanced serotonin signaling modulates the properties of the olfactory circuit, resulting in a change in olfaction. To test this hypothesis and characterize the molecular and cellular mechanisms of this learning process, we will first use genetic ablation and laser surgery to map the neural circuit underlying the olfactory learning and define the neuronal components of this network. Then we will use calcium imaging to examine the neuronal properties of the olfactory circuit in both na¿ve and learned animals. And finally we will use molecular genetics and biochemical tools to characterize how the training experience generates a neuromodulatory serotonin signaling through CaMKII and a Gq signaling pathway. PUBLIC HEALTH RELEVANCE: Olfactory learning is one of the fundamental forms of neural plasticity that enables us to interact with environment and to learn from experience. However, many people suffer from different forms of disabilities in learning and memory that are associated with varies devastating neurological diseases and are seriously compromised in their ability to develop or maintain their mental capacities, which often result in a marginal life quality. Little is known about the molecular and cellular pathology of these neurological defects. Our basic research on the mechanisms of olfactory learning will help us understand the physiological requirements of normal learning processes, provide insights into the basis of mental disability and guide potential treatments for these devastating neurological disorders.

描述（由申请人提供）：我们有兴趣了解个人如何通过嗅觉与环境进行交流，特别是嗅觉反应如何通过经验和环境线索进行塑造和修改。为此，我们使用的遗传模式生物秀丽隐杆线虫和一种新形式的嗅觉可塑性在这个动物模型中提出以下问题：什么是嗅觉学习的神经元回路的功能组织？经验如何产生调节线索来改变嗅觉？嗅觉回路的内在属性是如何随着经验的变化而变化，从而产生嗅觉学习的？我们以前证明了C。线虫在摄入病原体后学会避免病原菌的气味。来自一对肾上腺素能神经元ADF和嗅觉回路的5-羟色胺信号传导对于指导这个学习过程是必不可少的。感染的生理应激通过CaMKII和Gq通路增强ADF 5-羟色胺信号;并且增强的信号传导通过几个中间神经元中的胡萝卜素门控通道促进学习。这种学习的发生需要两对感觉神经元下游的嗅觉神经回路。我们推测，增强的5-羟色胺信号调节嗅觉回路的特性，导致嗅觉的变化。为了验证这一假设，并表征这种学习过程的分子和细胞机制，我们将首先使用基因消融和激光手术来绘制嗅觉学习的神经回路，并定义该网络的神经元组成部分。然后，我们将使用钙成像来检查幼稚和学习动物嗅觉回路的神经元特性。最后，我们将使用分子遗传学和生物化学工具来表征训练经验如何通过CaMKII和Gq信号通路产生神经调节性5-羟色胺信号。公共卫生相关性：嗅觉学习是神经可塑性的基本形式之一，使我们能够与环境互动并从经验中学习。然而，许多人在学习和记忆方面患有不同形式的残疾，这些残疾与各种毁灭性的神经系统疾病有关，严重损害了他们发展或维持智力的能力，这往往导致生活质量低下。对这些神经缺陷的分子和细胞病理学知之甚少。我们对嗅觉学习机制的基础研究将帮助我们了解正常学习过程的生理要求，深入了解精神残疾的基础，并指导这些毁灭性神经系统疾病的潜在治疗。