Molecular Dissection of the "Pacman-Flux" Machinery Used to Move Chromosomes

用于移动染色体的“Pacman-Flux”机器的分子解剖

• 批准号: 7477079
• 负责人: DAVID James SHARP
• 金额: $ 34.86万
• 依托单位: ALBERT EINSTEIN COLLEGE OF MEDICINE
• 依托单位国家: 美国
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-08-15 至 2011-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7477079
• 关键词: Anaphase; Biochemical; Cell division; Cells; Centrosome; Chromatids; Chromosome Segregation; Chromosomes; Class; Complement; Congenital Abnormality; Defect; Depth; Dissection; Drosophila genus; Drosophila melanogaster; Embryo; Enzymes; Etiology; Goals; Homologous Gene; Human; Imagery; Kinesin; Kinetochores; Lead; Life; Malignant Neoplasms; Microscopic; Microtubule Depolymerization; Microtubules; Minus End of the Microtubule; Mitosis; Mitotic spindle; Modeling; Molecular; Motion; Motor; Pathway interactions; Phosphorylation; Plus End of the Microtubule; Process; Protein Array; Proteins; Purpose; Recruitment Activity; Regulation; Sister Chromatid; System; Techniques; Testing; Therapeutic; Tubulin; Work; base; cell motility; depolymerization; embryo cell; insight; katanin; polymerization; protein function; spastin; tissue/cell culture; tumorigenesis

DESCRIPTION (provided by applicant): The ability of chromosomes to move towards opposite poles of the mitotic spindle is fundamental for proper cell division and defects in this process are believed to be an initial step in tumorigenesis. Poleward chromosome motility occurs by a "Pacman-flux" mechanism: Chromosomes induce the depolymerization of attached microtubule plus-ends, termed "Pacman", while being reeled into spindle poles by poleward tubulin flux" stimulated by depolymerization of microtubule minus-ends. The goal of the studies outlined in this proposal is to elucidate the molecular machinery that stimulates and controls "Pacman-flux"-based chromosome motility. The central hypothesis of this work is that chromosome motility is controlled by a mechanistically diverse array of proteins which employ distinct targeting and mechanisms-of-action to control the polymerization state of microtubule ends. There are two specific aims: Aim 1) Elucidate the molecular pathway that stimulates and controls the velocity of microtubule minus-end depolymerization and poleward flux. Studies in this aim evaluate the flux-related functions of microtubule severing proteins, multiple kinesin-13s and kinesin-13 phosphorylation. Aim 2) Elucidate the molecular pathway by which chromosomes induce the depolymerization of microtubule plus-ends. Studies in this aim evaluate the Pacman-related functions of CLIP-170/190, microtubule severing proteins, and multiple kinesin-13s. The fruit fly Drosophila melanogaster is the primary experimental system used in these studies. Live cell techniques for visualizing spindle and chromosome dynamics have been optimized in Drosophila S2 cells and embryos and thus these cells provide an ideal context within which to study how the manipulation of protein function impacts "Pacman-Flux". Live cell microscopic studies of mitosis will be complemented by biochemical and molecular approaches to provide an in-depth understanding of whether and how specific classes of proteins drive chromosome segregation. Additional studies are performed in human cells to determine whether aspects of our proposed pathways are evolutionary conserved. Defects in chromosome segregation lead to human maladies such as birth defects and cancer. An understanding of how this process occurs normally should provide insights into the molecular etiology of these diseases and suggest therapeutic strategies for their treatment.

描述（由申请人提供）：染色体向有丝分裂纺锤体的相反两极移动的能力是正常细胞分裂的基础，该过程中的缺陷被认为是肿瘤发生的初始步骤。向极的染色体运动通过“Pacman通量”机制发生：染色体诱导附着的微管正末端的解聚，称为“Pacman”，同时通过微管负末端解聚刺激的向极的微管蛋白通量”被卷绕到纺锤体极中。在这个建议中概述的研究的目标是阐明的分子机制，刺激和控制“吃豆人通量”为基础的染色体运动。这项工作的中心假设是，染色体运动是由一个机械多样的蛋白质阵列，采用不同的靶向和机制的行动，以控制微管末端的聚合状态控制。有两个具体目标：目的1）阐明刺激和控制微管负端解聚和向极流动速度的分子途径。在这个目标的研究评估微管切断蛋白，多个驱动蛋白-13和驱动蛋白-13磷酸化的流量相关的功能。目的2）阐明染色体诱导微管加端解聚的分子途径。在这一目标的研究评估的CLIP-170/190，微管切断蛋白，和多个驱动蛋白-13的Pacman相关的功能。果蝇Drosophila melanogaster是这些研究中使用的主要实验系统。用于可视化纺锤体和染色体动力学的活细胞技术已经在果蝇S2细胞和胚胎中进行了优化，因此这些细胞提供了一个理想的背景，在其中研究蛋白质功能的操纵如何影响“Pacman-Flux”。有丝分裂的活细胞显微镜研究将通过生物化学和分子方法进行补充，以深入了解特定类别的蛋白质是否以及如何驱动染色体分离。在人类细胞中进行了额外的研究，以确定我们提出的途径的各个方面是否是进化保守的。染色体分离的缺陷导致人类疾病，如出生缺陷和癌症。了解这一过程通常如何发生，应提供深入了解这些疾病的分子病因，并提出治疗策略。