权益分类	功能权益	普通用户	{{item.name}}会员
{{category.name}}	{{benefitItem.name}}

Synaptic Mechanisms of Hypothalamic Control of Vigilance and Cognitive Function

下丘脑控制警觉和认知功能的突触机制

基本信息

批准号：
8502559
负责人：
Alexander Choi Jackson
金额：
$ 1.1万
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：
2012
资助国家：
美国
起止时间：
2012-07-01 至 2013-08-15
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8502559
关键词：
Acetylcholine Address Animals Arousal Attention Award Behavior Behavior Control Behavioral Behavioral Genetics Behavioral Model Brain Cells Circadian Rhythms Cognition Cognitive Complex Dementia Disease Dopamine Electroencephalography Electrophysiology (science)Fiber Frequencies Functional disorder Genetic Goals Health Heterogeneity Histamine Human Hypothalamic structure In Vitro Institution Investigation Laboratories Lead Learning Link Maintenance Mediating Memory Mental Health Mental disorders Mentors Methods Mus Neurologic Neurons Neurosciences Research Neurotransmitters Norepinephrine Patch-Clamp Techniques Pathway interactions Patients Pattern Performance Pharmaceutical Preparations Pharmacology Play Positioning Attribute Postdoctoral Fellow Preparation Principal Investigator Probability Psyche structure Regulation Research Research Proposals Role Schizophrenia Signal Transduction Sleep Sleep Architecture Slice Son Specificity Synapses System Techniques Testing Therapeutic Intervention Training Transgenic Mice Wakefulness Work awake basal forebrain base career cell type cholinergic cognitive function gamma-Aminobutyric Acid improved in vivo innovation mammilloinfundibular nucleus structure millisecond multidisciplinary nervous system disorder neural circuit neuropsychiatry neurotransmission neurotransmitter release new technology novel optogenetics patch clamp public health relevance research study tool transmission process vigilance

项目摘要

DESCRIPTION (provided by applicant): The overall goal of this research proposal is to better understand how hypothalamic histaminergic (HA) projec- tion neurons control behavioral state transitions and cognitive performance, using electrophysiological, genetic and behavioral methods in transgenic mice. The applicant for the K99/R00 Pathway to Independence Award, Dr. Alexander C. Jackson, is currently a postdoctoral fellow in Dr. Roger Nicoll's laboratory at UCSF. Dr. Jack- son's long-term research goal is to elucidate the cellular, synaptic and circuit-level mechanisms through which hypothalamic neural circuits regulate fundamental behavioral states, such as sleep, wakefulness, attention and cognition, in health and disease. Dr. Jackson's long-term career goal is to lead a basic neuroscience research laboratory as a tenure-track principal investigator in an academic research institution. Many of the neuro- transmitter pathways in the brain that are implicated in the pathophysiology of neuropsychiatric illnesses are inexorably linked to those known to regulate sleep, wakefulness and circadian rhythms. Multiple lines of evi- dence implicate the hypothalamic HA system in regulating wakefulness, attention and aspects of cognitive function. Moreover, novel drugs that selectively enhance the activity of HA neurons are promising in promoting wakefulness and boosting cognitive function in disorders such as schizophrenia and dementias. However, largely owing to the heterogeneity of hypothalamic circuits, our understanding of the fundamental mechanisms of HA-mediated neurotransmission and its role in behavior is gravely lacking. As part of his research proposal, Dr. Jackson will circumvent current limitations in probing hypothalamic circuits by employing a cutting-edge optogenetic strategy to manipulate the excitability of genetically targeted HA neurons with millisecond preci- sion, in both brain slices and awake/behaving animals. By building on his training in cellular and synaptic elec- trophysiology, he will pursue additional training in optogenetics, EEG/EMG recording and behavioral analysis with his co-mentor Dr. Luis de Lecea (Stanford). Using these new tools, he will interrogate the HA system in a multidisciplinary manner through three Specific Aims: 1) To use novel optogenetic techniques to specifically target HA neurons with channelrhodopsin (ChR2) and then apply whole-cell patch clamp electrophysiology in brain slices to determine the synaptic mechanisms underlying the regulation of target neuron excitability by en- dogenous HA release (mentored). 2) To elucidate the role of HA neurotransmission in general arousal, sleep- wake transitions and cognitive performance, by optogenetically activating HA neurons in vivo, and quantifying cortical activation, sleep-wake transitions and cognitive function through two behavioral models of learning and memory (mentored). 3) To determine the role of co-transmission in the HA system, by assessing the possibil- ity of HA/GABA co-release, its target cell-specificity and its functional role in sleep-wake behavior and cognition (independent). The training period afforded by the K99/R00 Award will provide Dr. Jackson with a powerful toolbox for his independent career investigating hypothalamic function in health and disease.

描述（由申请人提供）：本研究提案的总体目标是使用转基因小鼠的电生理、遗传和行为方法，更好地了解下丘脑组胺能（HA）投射神经元如何控制行为状态转换和认知表现。K99/R 00独立之路奖的申请人，亚历山大博士。杰克逊目前是加州大学旧金山分校罗杰·尼科尔博士实验室的博士后研究员。Jack- son博士的长期研究目标是阐明下丘脑神经回路在健康和疾病中调节基本行为状态（如睡眠、觉醒、注意力和认知）的细胞、突触和回路水平机制。杰克逊博士的长期职业目标是在一家学术研究机构担任终身首席研究员，领导一个基础神经科学研究实验室。大脑中的许多神经递质通路与神经精神疾病的病理生理学有关，它们与已知的调节睡眠、觉醒和昼夜节律的通路有着不可分割的联系。多种证据表明下丘脑HA系统调节觉醒、注意力和认知功能。此外，选择性增强HA神经元活性的新型药物在促进精神分裂症和痴呆等疾病的觉醒和增强认知功能方面很有希望。然而，很大程度上由于下丘脑回路的异质性，我们对HA介导的神经传递的基本机制及其在行为中的作用的理解严重缺乏。作为其研究计划的一部分，杰克逊博士将采用尖端的光遗传学策略，在脑切片和清醒/行为动物中以毫秒精度操纵遗传靶向HA神经元的兴奋性，从而规避当前探测下丘脑回路的限制。通过在细胞和突触神经生理学方面的培训，他将与他的共同导师Luis de Lecea博士（斯坦福大学）一起进行光遗传学、EEG/EMG记录和行为分析方面的额外培训。使用这些新工具，他将通过三个具体目标以多学科方式询问HA系统：1）使用新颖的光遗传学技术以通道视紫红质（ChR 2）特异性靶向HA神经元，然后在脑切片中应用全细胞膜片钳电生理学以确定内源性HA释放（指导）调节靶神经元兴奋性的突触机制。2)通过体内光遗传学激活HA神经元，并通过两种学习和记忆行为模型（指导）定量皮质激活、睡眠-觉醒转换和认知功能，阐明HA神经传递在一般觉醒、睡眠-觉醒转换和认知表现中的作用。3)通过评估HA/GABA共释放的可能性、其靶细胞特异性及其在睡眠-觉醒行为和认知（独立）中的功能作用，确定共传递在HA系统中的作用。K99/R 00奖提供的培训期将为杰克逊博士提供一个强大的工具箱，用于他独立的职业生涯，调查健康和疾病中的下丘脑功能。