Genetic Control of Basal Telencephalic Development

基础端脑发育的遗传控制

基本信息

批准号：
7877717
负责人：
JOHN L. R. RUBENSTEIN
金额：
$ 38.63万
依托单位：
UNIVERSITY OF CALIFORNIA, SAN FRANCISCO
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：
2009-06-20 至 2014-04-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7877717
关键词：
Affective Alleles Autistic Disorder Basal Ganglia Basal Nucleus of Meynert Brain region Cell Nucleus Cells Chorea Cognition Cognitive Corpus striatum structure Defect Development Disease Embryo Embryonic Development Emotions Enhancers Figs - dietary Gene Expression Genes Genetic Gilles de la Tourette syndrome Globus Pallidus Grant Hippocampus (Brain)Huntington Disease Interneurons Label Learning Maps Medial Mediating Mental Retardation Modeling Molecular Analysis Morphology Motor Movement Movement Disorders Muscle Rigidity Neurons Paper Parkinson Disease Phenotype Property Proteins Publishing Role Schizophrenia Specific qualifier value Synapsins Telencephalon Testing Tremor Ventricular addiction cholinergic classical conditioning combinatorial developmental genetics mutant neocortical nervous system disorder progenitor public health relevance research study subventricular zone tool transcription factor

项目摘要

DESCRIPTION (provided by applicant): The cortex, striatum and pallidum are three key components of cortico-basal ganglia circuits - these circuits regulate limbic, associative and sensorimotor learning. The embryonic basal telencephalon generates subcortical nuclei and cortical interneurons that are required for the function of these circuits. As such, developmental defects of basal telencephalic development can have a profound influence on cognition, emotion and movement. Defects that alter sensorimotor learning can result in motor phenotypes, as exemplified by chorea, tremor and rigidity seen in disorders such as Huntington's disease and Parkinson's disease. Defects that alter limbic and associative learning can result in affective and cognitive defects that may underlie disorders such as Tourette's, Schizophrenia and addiction. The embryonic basal telencephalon primarily consists of the medial ganglionic eminence (MGE); it produces GABAergic and cholinergic projection neurons of the globus pallidus, nucleus basalis and adjacent regions, and GABAergic and cholinergic interneurons that disperse throughout the striatum and cortex. Thus, the basal telencephalon has a central role in generating components of cortical-basal ganglia circuits. An approach to elucidate the genetic underpinnings that regulate the basal telencephalon is to study the function of transcription factors that control the development and function of the neurons that are produced in this region. In this proposal, I describe experiments that study the functions of four transcription factors: Nkx2.1 (Aim 2), Lhx6 (Aim 3&4), Lhx7/8 (Aims 3&4) and Ldb1 (Aim 5). We hypothesize that combinatorial and unique functions of these four proteins participate in specifying the identity and properties of neurons generated by the embryonic basal telencephalon; the following schema provides the outline of our hypothesis. Aim 2 tests Nkx2.1 function in SVZ progenitors, pallidal projection neurons, and in the VZ of the most ventral regions of the basal telencephalon. Aim 3 studies how Lhx6 regulates MGE differentiation. Aim 4 tests whether Lhx6/Lhx7/8 coordinately regulate MGE development, and Aim 5 tests the function of Ldb1, and whether its phenotypes resemble Lhx6/7(8) mutants. In addition, we will perform fate mapping studies of cells produced in the embryonic basal telencephalon, using Cre-expressing alleles (Aim 1); these alleles will also be useful genetic tools for generating conditional mutants, such as in Aims 2 and 5. PUBLIC HEALTH RELEVANCE: The results from the proposed studies will provide basic information regarding the genetic and developmental mechanisms that control formation of brain regions that control cognition and movement. Disruption of these mechanisms can cause psychiatric and neurological disorders that include mental retardation, autism, schizophrenia, movement disorders and addiction.

描述（由申请人提供）：皮质，纹状体和苍白球是皮质 - 巴萨神经节电路的三个关键组成部分 - 这些电路调节边缘，联想和感觉运动学习。胚胎基底脑脑产生了皮质下核和皮质中间神经元，这些核元是这些电路功能所需的。因此，基础脑脑发育的发展缺陷会对认知，情感和运动产生深远的影响。改变感觉运动学习的缺陷会导致运动表型，如huntington病和帕金森氏病在诸如诸如亨廷顿氏病和帕金森氏病的疾病中所见的那样。改变边缘和联想学习的缺陷会导致情感和认知缺陷，这可能是诸如Tourette，精神分裂症和成瘾之类的疾病的基础。胚胎基底脑脑主要由内侧神经节显着性（MGE）组成；它产生了pallidus的GABA能和胆碱能投射神经元，底核和邻近区域，以及分散在整个纹状体和皮质中的Gabagagagric和胆碱能中间神经元。因此，基底脑脑在产生皮质 - 基质神经节电路的成分方面具有核心作用。一种阐明调节基底脑脑的遗传基础的方法是研究控制该区域产生的神经元的发育和功能的转录因子的功能。在此提案中，我描述了研究四个转录因子功能的实验：NKX2.1（AIM 2），LHX6（AIM 3＆4），LHX7/8（AIMS 3＆4）和LDB1（AIM 5）。我们假设这四种蛋白质的组合和独特功能参与指定由胚胎基底脑脑产生的神经元的身份和特性。以下模式提供了我们假设的概述。 AIM 2测试NKX2.1在SVZ祖细胞，苍白球投影神经元以及基底端脑最腹侧区域的VZ中的功能。 AIM 3研究LHX6如何调节MGE分化。 AIM 4测试LHX6/LHX7/8是否协调调节MGE的开发，AIM 5测试LDB1的功能，以及其表型是否类似于LHX6/7（8）突变体。此外，我们将使用表达CRE的等位基因（AIM 1）对在胚胎基底脑脑中产生的细胞进行命运映射研究；这些等位基因也将是产生条件突变体的有用遗传工具，例如AIM 2和5中。公共卫生相关性：拟议研究的结果将提供有关控制控制认知和运动的大脑区域形成的遗传和发育机制的基本信息。这些机制的破坏会导致精神病和神经系统疾病，包括智力障碍，自闭症，精神分裂症，运动障碍和成瘾。