CELL CYCLE CHECKPOINT CONTROL IN RESPONSE TO DNA DAMAGE

针对 DNA 损伤的细胞周期检查点控制

• 批准号: 6525868
• 负责人: NANCY C WALWORTH
• 金额: $ 29.84万
• 依托单位: UNIV OF MED/DENT NJ-R W JOHNSON MED SCH
• 依托单位国家: 美国
• 财政年份: 1995
• 资助国家: 美国
• 起止时间: 1995-08-01 至 2004-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6525868
• 关键词: DNA damage; Schizosaccharomyces pombe; alleles; binding sites; biological signal transduction; cell cycle; cell cycle proteins; cell growth regulation; enzyme activity; gene mutation; genetic mapping; genetic screening; immunoprecipitation; mutant; phenotype; phosphorylation; posttranslational modifications; protein kinase; protein protein interaction; protein structure function; protein transport; tissue /cell culture

The long-term goal of this project is to determine how cells regulate progression through the cell cycle when their DNA has been damaged. It has long been known that eukaryotic cells will delay progression through the cell cycle when the integrity of the genome has been compromised. In the last decade it has become clear that genetically defined signal transduction pathways, known as cell cycle checkpoints, couple the detection of DNA damage to control of cell cycle progression. The replication of damaged DNA templates or the segregation of damaged chromosomes can have catastrophic consequences for the integrity of the genome. Therefore, these checkpoint mechanisms play essential roles in maintaining genomic stability and, when compromised, can contribute to the onset of cancer or to cell death. Mutations in the human checkpoint pathway gene ATM, lead to the genetic disorder Ataxia Telangiectasia which is characterized by progressive neurodegeneration and a high incidence of cancer. The fission yeast, Schizosaccharomyces pombe, has proven to be an outstanding model system for identifying components of the cell cycle regulatory machinery as well as the DNA damage checkpoint pathway. The protein kinase Chk1, first identified in fission yeast, is required for cell cycle arrest when DNA is damaged. Homologues of Chkl have been identified in a variety of eukaryotic organisms including frogs, flies, worms and humans. In addition, an & pombe homologue of the ATM gene, rad3, has been shown to function on the same pathway as Chk1. To understand the role played by Chk1 in the DNA damage checkpoint pathway, several approaches will be taken that capitalize on the ease with which genetic and biochemical analyses can be carried out with & pombe. Proteins that interact with Chk1 or which influence the activity of Chk1 will be identified in genetic screens that make use of novel checkpoint defective alleles of the chkl gene. The previously identified interaction between Chk1 and Rad24, another protein shown to play a role on the DNA damage checkpoint pathway, will be characterized in detail. Determinants of the subcellular localization of Chkl will be identified as the location of Chk1 in the cell has important implications both for the nature of signaling to Chk1 as well as for the nature of putative Chk1 targets. The requirement of posttranslational modification of Chk1 by phosphorylation will be analyzed by identifying the sites of phosphorylation induced by DNA damage and analyzing the importance of those sites for Chkl function

这个项目的长期目标是确定当细胞的DNA受损时，细胞如何在细胞周期中调节进程。人们早就知道，当基因组的完整性受到损害时，真核细胞会推迟整个细胞周期的进展。在过去的十年中，基因定义的信号转导通路，称为细胞周期检查点，将DNA损伤的检测与细胞周期进程的控制结合在一起，这一点已经变得明显。复制受损的DNA模板或分离受损的染色体可能会对基因组的完整性造成灾难性的后果。因此，这些检查点机制在维持基因组稳定性方面发挥着至关重要的作用，当受到损害时，可能会导致癌症的发生或细胞死亡。人类检查点通路基因ATM的突变导致遗传性疾病共济失调毛细血管扩张症，其特征是进行性神经变性和癌症的高发病率。裂解酵母，裂殖酵母，已被证明是一个优秀的模式系统，以确定细胞周期调节机制的组成部分以及DNA损伤检查点途径。蛋白激酶Chk1最先在分裂酵母中被发现，当DNA受损时，它是细胞周期停滞所必需的。Chk1的同源物已经在包括青蛙、苍蝇、蠕虫和人类在内的各种真核生物中被发现。此外，ATM基因的An&pombe同源物Rad3已被证明与Chk1在相同的途径上发挥作用。为了了解Chk1在DNA损伤检查点途径中所起的作用，将采取几种方法来利用&pombe进行遗传和生化分析的简便性。与Chk1相互作用或影响Chk1活性的蛋白质将在利用Chk1基因新的检查点缺陷等位基因的遗传筛查中被识别。之前发现的Chk1和Rad24之间的相互作用将被详细描述，Rad24是另一种被证明在DNA损伤检查点途径上发挥作用的蛋白质。Chk1亚细胞定位的决定因素将被确定，因为Chk1在细胞中的位置对Chk1信号的性质以及可能的Chk1靶点的性质都有重要的影响。通过确定DNA损伤引起的磷酸化位点和分析这些位点对Chk1功能的重要性，将分析通过磷酸化修饰Chk1的翻译后修饰的需求