Subcellular targeting of light-responsive opsins for mapping and manipulating neu

光响应视蛋白的亚细胞靶向用于映射和操纵神经元

• 批准号: 8471775
• 负责人: DONALD B ARNOLD
• 金额: $ 37.34万
• 依托单位: UNIVERSITY OF SOUTHERN CALIFORNIA
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-30 至 2014-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8471775
• 关键词: Action Potentials; Affinity; Area; Axon; Behavior; Binding; Brain; Cations; Cells; Cytoskeleton; Dendrites; Diffusion; Distant; Epilepsy; Goals; Grant; Halorhodopsins; Health; Integral Membrane Protein; Ion Channel; Light; Location; MYO5A gene; Maps; Mediating; Mental Depression; Messenger RNA; Methods; Motor; Myosin ATPase; Neurons; Opsin; Pattern; Peptides; Population; Protein Binding; Proteins; Pump; Rhodopsin; Signal Transduction; Site; Slice; Specificity; Technology; Time; Tissues; Work; improved; in vivo; interest; nervous system disorder; neural circuit; neuronal cell body; novel; patch clamp; postsynaptic; presynaptic; relating to nervous system; response

DESCRIPTION (provided by applicant): The goal of this proposal is to develop methods to target light-activated proteins, such as Channel Rhodopsin II (ChR2) and Halorhodopsin (NpHR), to specific subcellular compartments in neurons. Both ChR2 and NpHR generate electrical currents in response to light: ChR2, an ion channel, passes depolarizing cation current in response to blue light, whereas NpHR, a pump, generates hyperpolarizing Cl- currents in response to yellow light. Neurons expressing these proteins can be efficiently excited or inhibited with light. ChR2 and NpHR can thus be expressed in specific neuronal populations to determine if activity in these cells is sufficient and necessary to drive a function, for example a behavior. ChR2 has been used to map synaptic circuits in brain slices, by combining patch clamp recording of postsynaptic cells with stimulation of presynaptic neurons expressing ChR2. ChR2 can also be used to stimulate neurons in a spatial pattern in vivo, for example to determine motor maps. A major limitation to the use of light-activated proteins in circuit mapping is their tendency to localize nonspecifically to different neuronal compartments. ChR2 and NpHR appear to be expressed equally well in axons and dendrites. In most neural tissues, dendrites and local and long-range axons are intermingled. The presence of these proteins in axons means that photostimulation can have non-local effects. Thus, it is virtually impossible to stimulate dendrites from one ChR2-positive cell without also stimulating neighboring ChR2-positive axons that can arise from distant and functionally unrelated neurons. Similarly, action potential propagation can be blocked by photostimulation of NpHR-positive axons. It is therefore of great interest to generate versions of NpHR and ChR2 that can be excluded from axons, by targeting them to dendrites and somata. In other applications it is advantageous to specifically target light- activated proteins to axons. Here we propose to generate peptides encoding signals that target light-activated proteins to specific subcellular compartments allowing neurons to be activated or inhibited for neural circuit analysis.

描述（由申请人提供）：本提案的目标是开发将光激活蛋白（如通道视紫红质II（ChR 2）和盐视紫红质（NpHR））靶向神经元中特定亚细胞区室的方法。ChR 2和NpHR都能响应光产生电流：ChR 2是一种离子通道，响应蓝光传递去极化阳离子电流，而NpHR是一种泵，响应黄光产生超极化Cl-电流。表达这些蛋白质的神经元可以被光有效地激发或抑制。因此，ChR 2和NpHR可以在特定的神经元群体中表达，以确定这些细胞中的活性是否足以和必要地驱动功能，例如行为。ChR 2已被用于绘制脑切片中的突触回路，通过将突触后细胞的膜片钳记录与表达ChR 2的突触前神经元的刺激相结合。ChR 2也可用于在体内以空间模式刺激神经元，例如确定运动图。在电路映射中使用光激活蛋白的一个主要限制是它们倾向于非特异性地定位于不同的神经元隔室。ChR 2和NpHR似乎在轴突和树突中同样表达良好。在大多数神经组织中，树突以及局部和远程轴突是混合的。轴突中这些蛋白质的存在意味着光刺激可以具有非局部效应。因此，刺激来自一个ChR 2阳性细胞的树突而不刺激邻近的ChR 2阳性轴突几乎是不可能的，这些轴突可能来自遥远的和功能无关的神经元。类似地，动作电位传播可以被NpHR阳性轴突的光刺激阻断。因此，通过将NpHR和ChR 2靶向树突和胞体来产生可以从轴突中排除的NpHR和ChR 2的版本是非常有趣的。在其他应用中，将光激活蛋白特异性靶向轴突是有利的。在这里，我们建议产生肽编码信号，目标光激活蛋白质的特定亚细胞区室，允许神经元被激活或抑制神经回路分析。