Regulation and Significance of Sustained Circadian Oscillations

持续昼夜节律振荡的调节和意义

基本信息

批准号：
10297528
负责人：
CARL Hirschie JOHNSON
金额：
$ 32.48万
依托单位：
VANDERBILT UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2013
资助国家：
美国
起止时间：
2013-09-01 至 2025-05-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10297528
关键词：
Address Alpha Rhythm Antibiotics Bacteria Bacterial Model Biochemical Biochemical Reaction Bioinformatics Biological Biological Clocks Biological Models Biological Process Cardiovascular Diseases Cell Line Cell physiology Cells Characteristics Circadian Rhythms Complex Cyanobacterium Dimensions Disease Environment Environmental Risk Factor Escherichia coli Event Evolution Feeding Patterns Financial compensation Frequencies Future Gene Expression Gene Structure Genes Genetic Genomics Goals Growth Health Homeostasis Hour Human Jet Lag Syndrome Knowledge Lead Malignant Neoplasms Mental Depression Mental Health Mental disorders Metabolic Diseases Metagenomics Molds Molecular Mutation Natural Selections Network-based Organism Performance Periodicity Personal Satisfaction Phase Photoperiod Process Property Protocols documentation Public Health Recovery Regulation Role Signal Transduction Sleep Stress System Temperature Testing Time alertness base cell community cell growth regulation circadian circadian pacemaker circadian regulation fascinate feeding fitness fitness test gut microbiome hormone metabolism host microbiome host-microbe interactions improved information processing novel physical conditioning pressure progenitor response shift work temporal measurement therapy design therapy development transcriptome transcriptomics

项目摘要

Project Summary/Abstract Circadian (daily) rhythms are a crucial component of human health that regulates sleep, alertness, homeostasis, cellular signaling, and many other biological processes. The fascination of this phenomenon is to explain how a biochemical mechanism (i) can robustly sustain a long period (~24 h) oscillation whose frequency keeps time so precisely, and (ii) enhance fitness in the natural environment. These questions remain critically important unanswered issues in the circadian rhythms field. For example, the adaptive value is not clear for the most obvious circadian characteristic–a robust self-sustained oscillation in constant conditions. If “anticipation” of future temporal events (e.g., dawn, dusk, etc.) is the goal of circadian timekeepers, why is a temperature-compensated “hourglass timer” that is initiated by dawn or dusk not sufficient? And yet evolution ubiquitously selected an oscillator that sustains itself in non-natural continuous conditions as the timekeeper for regulating daily processes, and this characteristic forms a core defining property of circadian rhythms. The overall goal of this project is to determine which characteristics of rhythmic environments provide selective pressures that coordinate cellular organization of gene expression and information processing to promote properties of circadian timekeeping. Identifying the selective pressures & evolutionary steps that can lead to biological timekeeping will enable a more profound understanding of circadian mechanisms and signaling so that they might be reinforced to aid human health and performance. The unique characteristics of model systems will be harnessed to attain the goal of this project by a multifaceted approach. First, in free-living organisms, the circadian regulation of seasonal responses and circadian interactions within communities of cells will be investigated to determine why sustained oscillators are necessarily adaptive. Second, the temporal dimensions of host/microbiome relations will be manipulated to ascertain if the gut microbiome is under active selection for timekeeping ability. Finally, a novel experimental evolution approach will identify which environmental pressures can be selective for circadian clocks. The answers to these questions will help us to better understand general principles of fundamental circadian organization and rhythmic regulation of cellular physiology; this understanding can help us to better design therapies for disorders in which circadian clocks are implicated.

项目概要/摘要昼夜节律（每日）节律是人类健康的重要组成部分，它调节睡眠、警觉性、这种现象的魅力在于体内平衡、细胞信号传导和许多其他生物过程。解释生化机制 (i) 如何能够稳健地维持长时间（~24 小时）振荡，其频率使时间如此精确，并且（ii）增强自然环境中的适应性这些问题仍然存在。例如，昼夜节律领域中尚未解决的至关重要的问题不是适应性值。清楚地表明了最明显的昼夜节律特征——在恒定条件下的强大的自我维持振荡。对未来时间事件（例如黎明、黄昏等）的“预期”是昼夜节律计时器的目标，为什么在黎明或黄昏启动的温度补偿“沙漏计时器”还不够吗？普遍选择一个在非自然连续条件下维持自身的振荡器作为计时器调节日常过程，这一特征形成了昼夜节律的核心定义属性。该项目的总体目标是确定节奏环境的哪些特征提供了选择性协调基因表达和信息处理的细胞组织的压力，以促进识别昼夜节律计时的特性。生物计时将使我们能够更深刻地理解昼夜节律机制和信号传导，从而可以加强它们以帮助人类健康和表现。将利用模型系统的独特特征来实现该项目的目标首先，在自由生活的生物体中，季节反应和昼夜节律调节。将研究细胞群内的昼夜节律相互作用，以确定持续振荡的原因其次，宿主/微生物组关系的时间维度将被操纵。确定肠道微生物群是否处于计时能力的主动选择之下最后，一个新的实验。进化方法将确定哪些环境压力可以对生物钟进行选择性。这些问题的答案将帮助我们更好地理解基本原理这种对细胞生理学的昼夜节律组织和节律调节的理解可以帮助我们更好地设计针对与生物钟有关的疾病的疗法。