Network Properties of Circadian Clock Modulation and Entrainment

昼夜节律时钟调制和夹带的网络特性

• 批准号: 8435950
• 负责人: ORIE T SHAFER
• 金额: $ 32.57万
• 依托单位: UNIVERSITY OF MICHIGAN AT ANN ARBOR
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-12-01 至 2017-11-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8435950
• 关键词: Acute; Address; Adult; Behavioral; Behavioral Genetics; Brain; Circadian Rhythms; Communication; Coupled; Cues; Cyclic AMP; Development; Dorsal; Drosophila genus; Drosophila melanogaster; Environment; Fruit; Functional disorder; Genetic; Goals; Hour; Human; Imaging Device; Life; Light; Maintenance; Mammals; Masks; Measurement; Measures; Membrane; Mental Health; Metabolic; Methods; Modeling; Molecular Genetics; Nature; Nervous system structure; Neural Pathways; Neurons; Organism; Pacemakers; Pathology; Pathway interactions; Personal Satisfaction; Phase; Photoreceptors; Physiological; Play; Process; Property; Role; Second Messenger Systems; Sensory; Signal Transduction; Sleep; Techniques; Testing; Time; Use of New Techniques; Visual system structure; Work; base; cholinergic; circadian pacemaker; day length; fly; gamma-Aminobutyric Acid; imaging modality; light entrainment; molecular imaging; network models; neurochemistry; neurophysiology; psychologic; relating to nervous system; research study; second messenger; therapy design; tool

DESCRIPTION (provided by applicant): Breakthroughs in our understanding of circadian timekeeping in the brain will be necessary to ameliorate the metabolic and psychological pathologies that accompany human circadian misalignment. The goal of this proposal is to critically test and extend current models of clock neuron network modulation and entrainment in Drosophila. The nervous system of this fly has several remarkable features that make it a valuable model for circadian timekeeping. We have recently developed a new set of live-imaging tools for the interrogation of central neuron networks in the adult Drosophila brain. These methods have made it possible to measure Ca2+ and cAMP dynamics in central neuronal networks in concert with the acute stimulation of genetically defined neuronal subsets. Using these new techniques, coupled with well-established genetic, anatomical, and behavioral methods, we will investigate the neurophysiological basis of circadian modulation and entrainment, two closely related processes that are central to the pathologies associated with the circadian misalignment that accompanies modern life. In our first aim we will determine the roles that cholinergic and GABAergic modulation of critical ventral clock neurons plays in the entrainment of sleep/activity rhythms to light cycles. In our second aim, we will identify and physiologically characterize the neural light input pathways that modulate the circadian clock neuron network and genetically determine the roles these pathways play in light entrainment. In our third and final aim, we will employ new methods of circuit interrogation to determine the physiological nature of the modulatory connections between the ventral and dorsal clock neuron classes, how these connections are daily and seasonally adjusted, and will use genetic methods to identify the specific roles that two ventral-to-dorsal peptidergic connections play in the maintenance and adjustment of circadian timekeeping. The goal of this proposal is to advance our understanding of circadian timekeeping and entrainment in the brain. We believe that the fruits of this work will ultimately aid the development and implementation of interventions designed to alleviate the significantly adverse metabolic and psychological effects of circadian dysfunction. PUBLIC HEALTH RELEVANCE: The proper alignment of internal circadian clocks with the 24-hour rhythm of the environment is critical for human health and psychological well-being. New molecular imaging methods make it possible for the first time to examine the modulation of neuronal clocks within the brain of the fly, Drosophila melanogaster, an organism that continues to enrich and inform our understanding of circadian timekeeping in the brain. Here we propose experiments to understand how neuronal clocks are physiologically adjusted by internal and external cues, the results of which will ultimately aid in the development of interventions designed to alleviate the adverse metabolic and psychological effects of human circadian dysfunction.

描述（由申请人提供）：我们对大脑中昼夜节律计时的理解的突破对于改善伴随人类昼夜节律失调的代谢和心理病理是必要的。该提案的目标是严格测试和扩展果蝇中时钟神经元网络调制和夹带的当前模型。这种果蝇的神经系统有几个显著的特征，使其成为昼夜节律计时的宝贵模型。我们最近开发了一套新的实时成像工具，用于询问成年果蝇大脑中的中枢神经元网络。这些方法使得有可能测量与遗传定义的神经元亚群的急性刺激一致的中央神经元网络中的Ca 2+和cAMP动态。 使用这些新技术，再加上完善的遗传学，解剖学和行为学方法，我们将研究昼夜节律调节和夹带的神经生理学基础，这两个密切相关的过程是与伴随现代生活的昼夜节律失调相关的病理学的核心。 在我们的第一个目标中，我们将确定关键腹侧时钟神经元的胆碱能和GABA能调制在光周期的睡眠/活动节律的夹带中所起的作用。在我们的第二个目标中，我们将识别和生理特征的神经光输入途径，调节昼夜节律钟神经元网络和遗传确定这些途径在光夹带中发挥的作用。在我们的第三个也是最后一个目标，我们将采用新的方法的电路审讯，以确定腹侧和背侧的时钟神经元类之间的调制连接的生理性质，这些连接是如何每天和季节性调整，并将使用遗传方法来确定特定的角色，两个腹到背的肽能连接在维护和调整昼夜节律的计时。这项提议的目的是促进我们对昼夜节律计时和大脑夹带的理解。我们相信，这项工作的成果将最终有助于开发和实施旨在减轻昼夜节律功能障碍的代谢和心理影响的干预措施。 公共卫生关系：内部生物钟与环境的24小时节律的正确对齐对于人类健康和心理健康至关重要。新的分子成像方法使人们有可能第一次检查果蝇大脑内神经元时钟的调制，果蝇是一种生物体，它继续丰富和告知我们对大脑昼夜节律计时的理解。 在这里，我们提出的实验，以了解神经元时钟是如何通过内部和外部线索的生理调整，其结果将最终有助于开发旨在减轻人类昼夜节律功能障碍的不良代谢和心理影响的干预措施。