Plasticity of Vocal Control

声音控制的可塑性

基本信息

批准号：
7005711
负责人：
ELIOT A BRENOWITZ
金额：
$ 11.79万
依托单位：
UNIVERSITY OF WASHINGTON
依托单位国家：
美国
项目类别：
财政年份：
2003
资助国家：
美国
起止时间：
2003-01-01 至 2007-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7005711
关键词：
animal communication behavior behavioral /social science research tag gene expression gene targeting genetic mapping hormone regulation /control mechanism in situ hybridization learning molecular cloning neural plasticity neuroanatomy neuroendocrine system polymerase chain reaction psychobiology songbirds steroid hormone vocalization

项目摘要

DESCRIPTION (provided by applicant): The long-term goal of this research is to understand the neuroendocrine basis of behavior used in communication. The birdsong system is a valuable model because song is learned, and its neural circuits are sexually dimorphic, hormone sensitive, and plastic in adults. Seasonal plasticity of the song control system provides an especially interesting model of plasticity in vertebrate brains, and a continuing goal of this research program is to understand the mechanisms and functional consequences of these seasonal changes. The immediate goal of this application is to receive training in methods of molecular biology that will enable the candidate to extend his studies of plasticity of the song system to a molecular level of analysis. Brenowitz will learn gene cloning, mapping and targeting, single and double-label in situ hybridization, PCR, and nonviral cRNA transfection methods in the laboratory of Robert Steiner at the University of Washington (UW). The candidate will be trained by Paul Neiman of the Fred Hutchison Cancer Research Center in Seattle in the use of eDNA microarrays to analyze patterns of gene expression, and in bioinformatic methods for data analysis. Brenowitz will take a course on microarray analysis at the UW Center for Expression Arrays. Scott Edwards of UW will train Brenowitz in DNA sequencing methods. The candidate will "apprentice" at the Institute for Systems Biology in Seattle to learn current methods of proteomics and bioinformatics. UW has a strong research program, with particular strengths in birdsong, endocrinology, neuroscience, molecular biology, animal behavior, and hearing research. The candidate's appointments in the Depts. of Psychology, Zoology, and the Bloedet Hearing Research Center provide access to shared facilities that benefit his research program. The proposed research will address mechanisms and functional consequences of seasonal plasticity in the song system. Aims 1 & 2, will test the hypotheses that social enhancement of seasonal growth is mediated by auditory cues and involves increased neuronal recruitment. Aim 3 will test the hypothesis that afferent innervation is necessary to maintain seasonally grown song nuclei. Aim 4 will test the hypothesis that seasonal growth of song circuits is mediated by estrogenic metabolites of testosterone. Aim 5 will use operant conditioning to test the hypothesis that seasonal plasticity of the song nuclei causes seasonal changes in song perception. Aim 6 will use in situ hybridization to test the hypothesis that expression of the gene for brain derived neurotrophic factor is upregulated when the song circuits are seasonally growing. Aim 7 will use subtractive suppressive hybridization to identify genes that are enriched in a song nucleus that grows seasonally compared with a nucleus that does not grow. Aim 8 will use a customized eDNA microarray to analyze global patterns of gene expression that are associated with seasonal growth of the telencephalic song control circuits. The results of the proposed studies will increase our understanding of the influences of steroid hormones and social stimuli on the nervous system, and the relationship between plasticity in the adult brain and learning.

描述（由申请人提供）：本研究的长期目标是了解交流行为的神经内分泌基础。鸟鸣系统是一个有价值的模型，因为鸣叫是后天习得的，而且它的神经回路具有性别二态性、激素敏感性，并且在成年人中具有可塑性。歌曲控制系统的季节性可塑性为脊椎动物大脑的可塑性提供了一个特别有趣的模型，该研究计划的持续目标是了解这些季节性变化的机制和功能后果。该应用程序的直接目标是接受分子生物学方法的培训，这将使候选人能够将其对歌曲系统可塑性的研究扩展到分子水平的分析。 Brenowitz 将在华盛顿大学 (UW) 的 Robert Steiner 实验室学习基因克隆、定位和靶向、单标记和双标记原位杂交、PCR 和非病毒 cRNA 转染方法。候选人将接受西雅图 Fred Hutchison 癌症研究中心的 Paul Neiman 培训，了解如何使用 eDNA 微阵列分析基因表达模式，以及如何使用生物信息学方法进行数据分析。 Brenowitz 将在华盛顿大学表达阵列中心学习微阵列分析课程。威斯康星大学的斯科特·爱德华兹 (Scott Edwards) 将对布伦诺维茨进行 DNA 测序方法方面的培训。候选人将在西雅图系统生物学研究所“学徒”，学习当前的蛋白质组学和生物信息学方法。华盛顿大学拥有强大的研究项目，尤其在鸟鸣、内分泌学、神经科学、分子生物学、动物行为和听力研究方面具有优势。候选人在部门的任命。心理学、动物学和布洛代特听力研究中心提供共享设施，这有利于他的研究项目。拟议的研究将解决歌曲系统中季节性可塑性的机制和功能后果。目标 1 和 2 将检验以下假设：季节性生长的社交增强是由听觉线索介导的，并且涉及神经元募集的增加。目标 3 将检验以下假设：传入神经支配对于维持季节性生长的鸣叫核是必要的。目标 4 将检验以下假设：歌曲回路的季节性增长是由睾酮的雌激素代谢物介导的。目标 5 将使用操作性条件反射来检验歌曲核的季节性可塑性导致歌曲感知的季节性变化的假设。目标 6 将使用原位杂交来检验以下假设：当歌曲回路季节性生长时，脑源性神经营养因子基因的表达上调。目标 7 将使用消减抑制杂交来识别与不生长的细胞核相比，季节性生长的细胞核中富集的基因。 Aim 8 将使用定制的 eDNA 微阵列来分析与端脑歌曲控制电路的季节性生长相关的基因表达的整体模式。拟议研究的结果将增进我们对类固醇激素和社会刺激对神经系统的影响以及成人大脑可塑性与学习之间关系的理解。