Functional Striatal Microcircuits in vivo and in vitro

体内和体外功能性纹状体微电路

• 批准号: 9343480
• 负责人: James M Tepper
• 金额: $ 5万
• 依托单位: RUTGERS THE STATE UNIV OF NJ NEWARK
• 依托单位国家: 美国
• 财政年份: 1997
• 资助国家: 美国
• 起止时间: 1997-02-01 至 2018-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/9343480
• 关键词: Action Potentials; Address; Affect; Afferent Neurons; Attention; Auditory; Basal Ganglia; Behavior; Behavioral; Brain; Cells; Corpus striatum structure; Cues; DRD2 gene; Data; Development; Dopamine D1 Receptor; Dopamine D2 Receptor; Electrophysiology (science); Exhibits; Experimental Designs; Genetic Techniques; Goals; Health; Housing; Imagery; In Vitro; Interneurons; Learning; Maps; Mediating; Methods; Molecular Genetics; Motor; Mus; Neostriatum; Neurologic; Neurons; Optics; Output; Pathway interactions; Performance; Phase; Physiological; Play; Population; Psychological reinforcement; Reaction Time; Research Design; Rewards; Role; Series; Specificity; Stimulus; Structure; Synapses; System; Testing; Text; Thalamic structure; Therapeutic Intervention; Tomatoes; Training; Transgenes; Transgenic Mice; Transgenic Organisms; Tyrosine 3-Monooxygenase; Viral; Whole-Cell Recordings; base; behavior measurement; behavior prediction; cell type; cholinergic; cholinergic neuron; cognitive function; disability; extracellular; in vivo; insight; interest; motor control; nerve supply; nervous system disorder; neural circuit; neuropsychiatric disorder; neuropsychiatry; novel; optogenetics; postsynaptic; presynaptic; promoter; rate of change; recombinase; research study; response; tool

DESCRIPTION (provided by applicant): The neostriatum is the main input structure of the basal ganglia, a system that is crucial not only for voluntary motor control, but also for reinforcement-mediated learning and higher cognitive functions. The importance of understanding the functioning of the nesotriatum is dramatically illustrated by the severe disability associated with numerous neurological and neuropsychiatric conditions that affect this brain structure. Developments in transgenic methods that allow visualization and targeting of genetically and functionally distinct types of neurons has recently led to the discovery of an unexpectedly large diversity of GABAergic interneurons in the neostriatum. As a result the striatum is now known to contain at least 7 types of GABAergic interneurons that include, in addition to the previously known fast spiking (FS) and the NPY expressing NPY-PLTS interneurons, 4 distinct classes of tyrosine hydroxylase (TH) containing interneurons and a new class of NPY expressing interneuron. We hypothesize, based on preliminary data and earlier studies, that the newly discovered TH and NPY interneurons are integral and important constituents of a highly organized intrastriatal synaptic circuitry and play essential roles in determining the activity and computational function of the neostriatum. The goal of the proposed studies is to understand the synaptic organization of this circuitry and to assess the functional significance of the newly discovered interneuron classes in determining the activity of other constituent neurons, in particular, the activity of functionally distinct types of projection neuros. The circuit organization of TH and NPY interneurons will be mapped in in vitro optogenetic experiments using a series of double transgenic mice in which expression of Cre-recombinase and EGFP in distinct types of neurons will allow high-throughput bidirectional analysis of the connectivity among TH, NPY, and FS interneurons and projection neurons of the direct and indirect pathways. The functional impact of TH and NPY interneurons will be assessed in in vivo optogenetic recording experiments in mice trained to perform operant tasks. First, we will examine how the firing rate of these interneurons varies in relation to distinct phases of the operant tasks. Next, we will examine how optogenetic manipulation (silencing or activation) of the activity of TH and NPY interneurons affects the firing rate of projection neurons, cholinergic and FS interneurons, how these manipulations affect local field potential oscillations, and how qualitative or quantitative measures of behavioral performance are affected. These experiments are expected to yield important new insights into the functioning of the neostriatum and may help to identify new cellular substrates for therapeutic interventions in a variety of neurological and neuropsychiatric disorders.

描述（由申请人提供）：新纹状体是基底神经节的主要输入结构，基底神经节是一个不仅对自主运动控制至关重要，而且对认知介导的学习和高级认知功能至关重要的系统。理解nesotriatum功能的重要性，通过与影响这一大脑结构的许多神经和神经精神疾病相关的严重残疾得到了戏剧性的说明。 转基因方法的发展，允许可视化和靶向的遗传和功能不同类型的神经元，最近导致发现了一个意想不到的大的多样性的GABA能中间神经元的新纹状体。结果，现在已知纹状体含有至少7种类型的GABA能中间神经元，除了先前已知的快速尖峰（FS）和表达NPY的NPY-PLTS中间神经元之外，还包括4种不同类别的含有酪氨酸羟化酶（TH）的中间神经元和一类新的表达NPY的中间神经元。我们假设，根据初步数据和早期的研究，新发现的TH和NPY中间神经元是一个高度组织化的纹状体内突触回路的组成部分和重要组成部分，并在确定新纹状体的活动和计算功能中发挥重要作用。拟议的研究的目标是了解该电路的突触组织，并评估新发现的中间神经元类在确定其他组成神经元的活动，特别是功能不同类型的投射神经元的活动中的功能意义。TH和NPY中间神经元的电路组织将在体外光遗传学实验中使用一系列双转基因小鼠进行映射，其中Cre重组酶和EGFP在不同类型的神经元中的表达将允许高通量双向分析TH、NPY和FS中间神经元以及直接和间接途径的投射神经元之间的连接。 TH和NPY中间神经元的功能影响将在体内光遗传学记录实验中在训练以执行操作任务的小鼠中进行评估。首先，我们将研究这些中间神经元的放电率如何随操作性任务的不同阶段而变化。接下来，我们将研究TH和NPY中间神经元的活性的光遗传学操纵（沉默或激活）如何影响投射神经元、胆碱能神经元和神经元的放电速率。 和FS中间神经元，这些操作如何影响局部场电位振荡，以及如何影响行为表现的定性或定量测量。 这些实验有望对新纹状体的功能产生重要的新见解，并可能有助于确定各种神经系统疾病治疗干预的新细胞基质。 和神经精神疾病。