Plasticity of auditory electrical synapses

听觉电突触的可塑性

基本信息

批准号：
9889922
负责人：
Alberto E Pereda
金额：
$ 56.59万
依托单位：
ALBERT EINSTEIN COLLEGE OF MEDICINE
依托单位国家：
美国
项目类别：
财政年份：
2010
资助国家：
美国
起止时间：
2010-07-01 至 2022-01-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9889922
关键词：
Adult Anatomy Auditory Auditory system Behavior Cells Chemical Synapse Chemicals Chemosensitization Communication Complement Complex Confocal Microscopy Connexins DNA Sequence Alteration Data Dopamine Electrical Synapse Electron Microscopy Electrophysiology (science)Excision Fishes Freezing Functional disorder Gap Junctions Goldfish Image Larva Life M cell Mediating Methods Modeling Modification Molecular Monitor Movement Neuromodulator Neurotransmitter Receptor Optics Pharmacology Property Proteins Protocols documentation Regulation Reporting Research Scaffolding Protein Structure Synapses Synaptic Transmission Testing Time Transgenic Organisms Work Zebrafish auditory pathway auditory processing base dorsal cochlear nucleus electrical property gap junction channel genetic manipulation genetic regulatory protein in vivo in vivo imaging membrane flux multiphoton microscopy neural circuit neuronal circuitry new therapeutic target novel optogenetics relating to nervous system trafficking transmission process

项目摘要

Abstract Gap junction (GJ)-mediated electrical synapses were recently reported to underlie important network properties in the dorsal cochlear nucleus and anatomical evidence suggests they are widespread along the auditory pathway. However, the properties of auditory electrical synapses remain poorly understood. As their chemical counterparts, electrical synapses are ‘plastic’, that is, they modify their strength with activity. Changes in the strength of electrical synapses dynamically reconfigure neuronal circuits in various neural structures. Thus, the presence and plastic properties of electrical synapses could fundamentally change the way we understand the organization of auditory circuits and, ultimately, the processing of auditory information. This proposal aims to contribute to our understanding of electrical transmission in the auditory system by investigating the molecular mechanisms causing plastic changes in GJ communication at mixed, electrical and chemical, contacts that couple primary auditory afferents to the Mauthner (M-) cells in fish. Our work in goldfish shows that electrical (and chemical) transmission at these mixed synapses undergo activity-dependent potentiation. Because these dynamic properties were later found to occur at mammalian electrical synapses. M-cell mixed synapses are considered a valuable model to study plasticity of vertebrate electrical transmission. In contrast to chemical synapses, little is known about the molecular mechanisms that underlie changes in the strength of electrical synapses. It is currently thought that plastic changes in GJ conductance are due to direct modification of the properties of already existing channels. However, our progress suggests that regulated insertion and removal of GJ channels may also contribute to plasticity. We propose to investigate the contribution of regulated trafficking of GJ channels to plastic changes of electrical transmission and its molecular underpinnings. To directly examine this possibility, we will take these unique model mixed synapses to a new level of analysis by investigating their properties in larval zebrafish. The amenability of zebrafish larvae to image the movement of fluorescently-tagged GJ channels in-vivo should allow monitoring of active synapses undergoing plasticity. This approach will provide an unprecedented window for the analysis of electrical transmission at which detailed molecular mechanisms will be investigated by combining in-vivo imaging, electrophysiology and time-resolved ultrastructural analysis with powerful genetic manipulations. Aim 1 is to investigate the conditions under which electrical synapses in larval zebrafish undergo potentiation. By combining electrophysiology and pharmacology with electrical and optogenetic stimulation, this aim will identify the conditions under which larval mixed synapses undergo potentiation of electrical (and chemical) transmission. Aim 2 is to test whether insertion and removal of GJ channels are required for plastic changes. This aim will explore the notion that electrical synapses are complex synaptic structures at which channels turnover and that their proper function and regulation results from interactions between multiple proteins. The description of novel molecular mechanisms involved in their regulation will contribute to a better understanding of the dynamics of circuits relevant to auditory dysfunction and the potential identification of novel therapeutic targets.

抽象的 GAP连接点（GJ）介导的电突触最近据报道是重要的网络背部人工耳蜗核和解剖学证据的特性表明，它们是广泛的主题听觉途径。化学对应物，电突触是“塑料”，用作用使其肌肉发达。电气突触的强度，在各种神经结构中动态重新配置神经元回路。因此，电气突触的存在和塑性特性可以筹集资金改变我们的wee wee wee wee wee wee wee。了解听觉电路的组织以及最终的听觉信息。提案旨在通过通过研究分子机制，导致混合，电气和电气在GJ通信中的塑性变化以及化学，接触我们在金鱼中的Mauthner（M-）细胞的主要听觉传入。表明混合突触突触中的电气（和化学）传播Syndergo依赖性增强性。 M细胞混合突触被认为是研究脊椎动物电气传播塑料的宝贵模型。与化学突触相反，对您的分子机制几乎不知道电气突触的强度。修改Alleyady现有渠道的属性。插入和去除GJ通道也可能有助于我们调查您。 GJ通道的常规运输对电气传输的塑性变化的贡献，IS是ISTS 分子的基础。通过研究其在幼虫斑马鱼中的特性来进行新的分析。幼虫，以形象荧光标记的GJ通道的运动，应允许监视活动突触使用这种方法。电气传输将通过组合体内研究详细的分子机制具有强大的遗传操作的成像，电生理学和时间分辨的超结构分析 1是研究幼虫斑马鱼中的电突触的条件。将电生理学和药理学与电气和光遗传学刺激相结合，目的是识别幼虫混合突触的条件）传输目标是测试。这个目标将探讨电气突触是复杂的突触结构的观念营业额和适当的功能和调节是由多种蛋白质之间的相互作用对其调节所涉及的新分子机制的描述将有助于更好地理解与听觉功能障碍和潜在治疗疗法有关的电路动力学目标。