Fragility and Instability at Hairpin-Forming Trinucleotide Repeats in Yeast

酵母中形成发夹的三核苷酸重复序列的脆弱性和不稳定性

• 批准号: 7192315
• 负责人: CATHERINE H FREUDENREICH
• 金额: $ 30.9万
• 依托单位: TUFTS UNIVERSITY MEDFORD
• 依托单位国家: 美国
• 财政年份: 2001
• 资助国家: 美国
• 起止时间: 2001-05-01 至 2011-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7192315
• 关键词: Affect; Biological Assay; Biological Models; CAG repeat; Cell Cycle; Cell Cycle Progression; Cell Death; Cell Survival; Cells; Chromatin; Chromatin Structure; Chromosome Breakage; Chromosome Fragility; Chromosomes; Complex; DNA; DNA Damage; DNA Repair; DNA biosynthesis; DNA damage checkpoint; Development; Disease; Eukaryota; Eukaryotic Cell; Failure; Fluorescence; Funding; Gel; Genes; Genetic; Genetic Screening; Genome; Genome Stability; Genomic Instability; Goals; Growth; Health; Hereditary Disease; Histones; Human; Human Genome; Huntington Disease; Inherited; Laboratories; Lead; Length; Link; Maintenance; Methods; Modeling; Modification; Monitor; Myotonic Dystrophy; Numbers; Pathway interactions; Phase; Play; Protein Binding; Proteins; Recruitment Activity; Relative (related person); Research; Research Personnel; Role; Saccharomyces cerevisiae; Screening procedure; Single Strand Break Repair; Spinocerebellar Ataxias; Structure; System; Techniques; Testing; Time; Trinucleotide Repeat Expansion; Trinucleotide Repeats; Two-Dimensional Gel Electrophoresis; Work; Yeasts; base; brain cell; chromatin immunoprecipitation; chromatin remodeling; coping; expectation; genetic pedigree; human disease; improved; insight; novel; prevent; programs; repaired; research study; response; size; success

DESCRIPTION (provided by applicant): Trinucleotide repeat sequences (TNRs), such as CAG/CTG repeats, expand in the human genome to cause 17 inherited human diseases, including Huntington's disease, myotonic dystrophy, and spinocerebellar ataxias. The strong hairpin-forming potential of these sequences is the likely basis for genome instability at expanded TNRs. Expanded TNRs inhibit repair of DNA gaps, interfere with DNA replication, and cause chromosomes to break (chromosome fragility). The goal of our research is to elucidate the cellular mechanisms that normally facilitate replication and repair of TNRs and determine how failure of these systems can lead to repeat expansion and chromosome breakage. We propose to characterize the role of proteins involved in DNA repair, the DNA damage checkpoint, and chromatin modification in preventing CAG/CTG repeat fragility and expansion, using Saccharomyces cerevisiae as a model system. The repair response to naturally occurring damage at strong hairpin-forming sequences will be investigated by using chromatin immunoprecipitation and fluorescence techniques to determine the identity and timing of repair protein recruitment to expanded TNRs. To establish the cellular consequences of DNA damage checkpoint activation by TNRs, division of single cells containing long CAG/CTG repeats will be monitored, and the role of the DNA damage checkpoint in preventing replication fork stalling at long repeats ascertained by 2-D gels. A novel link between TNR stability and chromatin structure will be investigated by determining the state of histone modifications and spacing at expanded TNRs. Lastly, we propose a genetic screen to identify additional proteins and pathways important in preventing chromosome fragility at CAG/CTG tracts. An understanding of how repair of CAG/CTG sequences occurs is important both to explain how repeat expansion diseases occur and to prevent pathological somatic expansions in non-dividing brain cells in Huntington's disease. Since cell death is a major factor in progression of several TNR diseases, determining the consequences of damage at expanded repeats for cell health could lead to strategies to slow disease development. The human genome contains many direct and inverted repeats and other types of sequences that present potential problems during replication and repair, so understanding the cellular mechanisms that have evolved to cope with these problems should yield important insights into genome stability.

描述(申请人提供)：三核苷酸重复序列(TNR)，如CAG/CTG重复，在人类基因组中扩展，导致17种遗传性人类疾病，包括亨廷顿病、强直性肌营养不良和脊髓小脑性共济失调。这些序列强大的发夹形成潜力可能是扩大的TNR基因组不稳定的基础。扩展的TnRs抑制DNA缺口的修复，干扰DNA复制，并导致染色体断裂(染色体脆性)。我们研究的目的是阐明正常情况下促进TNR复制和修复的细胞机制，并确定这些系统的故障如何导致重复扩张和染色体断裂。我们建议以酿酒酵母为模型系统，研究参与DNA修复、DNA损伤检查点和染色质修饰的蛋白质在防止CAG/CTG重复序列脆性和扩张中的作用。将通过使用染色质免疫沉淀和荧光技术来研究在强发夹形成序列上对自然发生的损伤的修复反应，以确定修复蛋白募集到扩展的TnRs的身份和时机。为了确定TnRs激活DNA损伤检查点的细胞后果，将监测含有长CAG/CTG重复的单细胞的分裂，并通过2-D凝胶确定DNA损伤检查点在防止长重复复制叉处停滞中的作用。TNR稳定性和染色质结构之间的一个新的联系将通过确定组蛋白修饰的状态和扩展的TnRs的间距来研究。最后，我们提出了一种基因筛查，以确定在防止CAG/CTG区染色体脆性方面重要的额外蛋白质和途径。了解CAG/CTG序列的修复是如何发生的，对于解释重复扩张性疾病是如何发生的，以及防止亨廷顿病未分裂脑细胞的病理性躯体扩张都是重要的。由于细胞死亡是几种TNR疾病进展的主要因素，确定扩大重复对细胞健康造成的损害的后果可能导致减缓疾病发展的策略。人类基因组包含许多正向和反向重复序列以及其他类型的序列，这些序列在复制和修复过程中会出现潜在的问题，因此了解为应对这些问题而进化的细胞机制应该会对基因组稳定性产生重要的见解。