Circadian gating of cell division by the cyanobacterial oscillator

蓝藻振荡器对细胞分裂的昼夜节律门控

• 批准号: 8397389
• 负责人: SUSAN S GOLDEN
• 金额: $ 39.32万
• 依托单位: UNIVERSITY OF CALIFORNIA, SAN DIEGO
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-08-01 至 2016-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8397389
• 关键词: ATP phosphohydrolase; Address; Algae; Animal Model; Bacteria; Biological; Biological Clocks; Biological Models; Bypass; Cell Cycle; Cell Fractionation; Cell division; Cells; Cellular biology; Chromosome Segregation; Chromosomes; Circadian Rhythms; Clock protein; Complex; Coupling; Cyanobacterium; Cytokinesis; DNA; Data; Development; Event; Flow Cytometry; Fluorescence Recovery After Photobleaching; Gene Expression; Goals; Homologous Gene; Human; Image; Immunofluorescence Immunologic; Immunoprecipitation; Individual; Inherited; Lighting; Location; Mammalian Cell; Mammals; Mass Spectrum Analysis; Membrane; Methods; Microfluidics; Microscopy; Modeling; Monitor; Motion; Mutation; Pathway interactions; Periodicity; Phosphotransferases; Ploidies; Polyploidy; Process; Proteins; Relative (related person); Replication Initiation; Replication Origin; Reporter; Resolution; Role; Running; Signal Transduction; Sorting - Cell Movement; Structure; Synechococcus; System; Testing; Time; Tubulin; Variant; Work; cell type; cellular imaging; circadian pacemaker; daughter cell; insight; mutant; novel; overexpression; programs; segregation; time use; tumor progression

DESCRIPTION (provided by applicant): The timing of cell division is coordinated with other cyclic events, of other periodicities, in the lives of cells. From bacteria, to algae, to diverse cll types in mammals, the circadian biological clock controls the time of day during which cell division can occur. The mechanism and function of this time restriction, or gating, of cell divisio is poorly understood in any system, and such regulatory checkpoints in mammals are important factors in developmental programs and the progression of cancer. The overall goal of this project is to understand how and why circadian rhythms and cell division are interlocked. The circadian control of cell division in the cyanobacterium Synechococcus elongatus provides an elegant system in which to address questions that probe the interactions of the clock, the cytokinesis machinery, and the segregating chromosomes. This project seeks to answer: What is the biological role of the circadian checkpoint of cytokinesis? What are the components of the machinery that connect the circadian clock to cell division? Where are the clock oscillator components during the cell and circadian cycles and how are they inherited? And, is the partitioning of chromosomes in S. elongatus, whose ploidy levels oscillate with circadian rhythmicity, related to the gating of cell division? The specific aims will: (1) Define the components, through which the circadian clock regulates cell division, and determine the consequences of bypassing the cell division gate; (2) Discern the intracellular localization and dynamics of clock proteins during the circadian and cell division cycles; and (3) Elucidate the relationships among the clock, cytokinesis, and chromosome segregation. Existing mutants that bypass the circadian cell division checkpoint will be used to test hypotheses that address the role of the gate in protecting circadian precision, chromosome integrity, and/or cell-to-cell variations in gene expression. Mass spectrometry will identify factors that associate with the cell division machinery during the gating checkpoint. Time-lapse imaging of cells trapped in microfluidics chambers will enable simultaneous monitoring of cell division and circadian rhythms to assess the consequences of gating in individual wild-type cells and in mutants that bypass the circadian gate. Super-resolution Structured Illumination imaging will provide sufficient sensitivity and resolution to track the localization and dynamics of circadian oscillato proteins and tagged chromosomes in wild-type and mutant cells throughout the circadian and cell division cycles. Sorting and imaging flow cytometry methods will be used to assess ploidy changes in wild-type and mutant strains. This project will reveal how and why a circadian clock controls cell division, a coupling of timing circuits that occurs in mammalian cells as well as in cyanobacteria, and will provide novel insight into how cells inherit a sense of time. PUBLIC HEALTH RELEVANCE: This project will reveal how and why cell division is controlled by the circadian clock, a phenomenon that occurs in mammalian cells as well as in cyanobacteria. It will also provide insight into the faithful distribution of chromosomes to cells and the control of chromosome copy number, which in humans are factors in developmental programs and the progression of cancer.

描述（由申请人提供）：细胞分裂的时间与细胞生命中其他周期性的其他循环事件相协调。从细菌到藻类，再到哺乳动物中的各种cll类型，昼夜节律生物钟控制着一天中细胞分裂发生的时间。在任何系统中，对细胞分裂的这种时间限制或门控的机制和功能都知之甚少，而哺乳动物中的这种调节检查点是发育程序和癌症进展的重要因素。这个项目的总体目标是了解昼夜节律和细胞分裂是如何以及为什么相互关联的。在蓝细菌细长聚球藻细胞分裂的昼夜节律控制提供了一个优雅的系统，在其中解决的问题，探测时钟，胞质分裂机械，和分离染色体的相互作用。这个项目试图回答：细胞质分裂的昼夜节律检查点的生物学作用是什么？将生物钟与细胞分裂联系起来的机制有哪些组成部分？在细胞和昼夜节律周期中，时钟振荡器组件在哪里？它们是如何遗传的？染色体的分配是S. elongatus，其倍性水平振荡与昼夜节律，有关的门控细胞分裂？具体目标是：（1）定义生物钟调节细胞分裂的组成部分，并确定绕过细胞分裂门的后果;（2）识别生物钟和细胞分裂周期中时钟蛋白的细胞内定位和动态;（3）阐明时钟，胞质分裂和染色体分离之间的关系。绕过昼夜节律细胞分裂检查点的现有突变体将用于测试解决门在保护昼夜节律精确性、染色体完整性和/或基因表达中的细胞间变异中的作用的假设。质谱分析法将确定与细胞相关的因素 检查站的时候被人发现了微流体室中捕获的细胞的延时成像将能够同时监测细胞分裂和昼夜节律，以评估单个野生型细胞和绕过昼夜节律门的突变体中门控的后果。超分辨率结构照明成像将提供足够的灵敏度和分辨率，以跟踪在整个昼夜节律和细胞分裂周期中野生型和突变细胞中的昼夜节律振荡蛋白和标记染色体的定位和动态。分选和成像流式细胞术方法将用于评估野生型和突变株的倍性变化。该项目将揭示生物钟如何以及为什么控制细胞分裂，这是哺乳动物细胞和蓝藻中发生的计时电路的耦合，并将为细胞如何继承时间感提供新的见解。 公共卫生相关性：这个项目将揭示细胞分裂是如何以及为什么由生物钟控制的，这是一种发生在哺乳动物细胞和蓝藻中的现象。它还将深入了解染色体在细胞中的忠实分布和染色体拷贝数的控制，这在人类中是发育计划和癌症进展的因素。