Nonrecurrent rearrangements, genome architecture and neurodegenerative disease.

非复发性重排、基因组结构和神经退行性疾病。

• 批准号: 8310156
• 负责人: JAMES R. LUPSKI
• 金额: $ 53.7万
• 依托单位: BAYLOR COLLEGE OF MEDICINE
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-07-17 至 2014-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8310156
• 关键词: 17p11.2; Affect; Alzheimer' s Disease; Architecture; Autistic Disorder; Base Pairing; Behavior Disorders; Bioinformatics; Biological Assay; Characteristics; Charcot-Marie-Tooth Disease; Chromosomes; Clinical; Clinical Research; Code; Complex; Copy Number Polymorphism; DNA; DNA Sequence; DNA Sequence Rearrangement; Derivation procedure; Development; Diagnostic; Disease; Etiology; Event; Fluorescent in Situ Hybridization; Frequencies; Gene Dosage; Genes; Genetic Recombination; Genome; Genomics; Genotype; Grant; Haplotypes; Homologous Gene; Human; Human Genome; Individual; Laboratories; Lead; Learning; Link; Maps; Mediating; Medical Genetics; Medicine; Mental Retardation; Mutation; Neurodegenerative Disorders; Neurodevelopmental Disorder; Parents; Parkinson Disease; Patients; Phenotype; Positioning Attribute; Predisposition; Process; Proteins; Public Health; Publications; Recombinants; Recurrence; Resolution; Sampling; Schizophrenia; Southern Blotting; Stimulus; Syndrome; Therapeutic; Variant; Xq28; base; clinically relevant; cohort; college; comparative genomic hybridization; design; dosage; genome sequencing; genome-wide; homologous recombination; insight; nervous system disorder; segregation; trait

DESCRIPTION (provided by applicant): It has become apparent during the previous twenty years that many neurological disease traits do not result from coding region mutations within genes, but instead manifest because of alterations of the genome. Genomic disorders are a class of conditions that result from genomic rearrangements rather than base pair changes of DNA sequence. In general, two major types of rearrangements are observed: recurrent and nonrecurrent genomic changes. Recurrent rearrangements have a common size in different patients; in which the breakpoints occur at 'fixed' genomic positions, or breakpoint cluster regions. The breakpoints cluster in paralogous segments of the human genome (also referred to as low-copy repeats, LCRs, or segmental duplications, SDs) that facilitate a non-allelic homologous recombination (NAHR) by both stimulating and mediating the rearrangement. Nonrecurrent rearrangements can be of different sizes in different patients, but usually share a "smallest region of overlap" (SRO) in which the critical genomic contents and/or gene(s) reside. Genomic disorders produced by non-recurrent rearrangements provide a unique challenge for studies of genotype/phenotype correlations. The variable size and genomic content as well as the frequent co- occurrence of complex alterations (e.g. triplications and inversions) that can occur with nonrecurrent rearrangements add further complexity to interpreting the genome and gene variation in the context of each patient's clinical manifestations. We hypothesize that nonrecurrent rearrangements may occur by mechanisms that are distinct from homologous recombination mechanisms; our preliminary studies and recent publications from the first year of this stimulus grant strongly support this hypothesis. Furthermore, we suggested some nonrecurrent rearrangements may result because of specific genome architectural features causing susceptibility to such rearrangements. We plan to investigate these hypotheses in an attempt to learn "the rules" for mechanisms leading to nonrecurrent rearrangements. We will investigate these hypotheses experimentally by; 1) mapping breakpoints of duplication rearrangements, triplication rearrangements, and complex rearrangements. 2) performing bioinformatic analyses of the genomic region undergoing rearrangement, and 3) determining the products of recombination through direct DNA sequences of the recombinant junction; i.e. breakpoint sequencing. 4) studying marker genotypes by whole-genome arrays in trios that consist of patients with disease associated de novo complex rearrangements and their unaffected parents to surmise strand exchanges or potential template switches by the segregation of marker haplotypes. Finally, we will attempt to elucidate genes that may be important to these rearrangement processes by whole genome sequencing of personal genomes in subjects, or parents of these subjects, with multiple de novo CNV events. In this manner we will identify the substrates for recombination, gain insights into genome architecture in regions involved, and potentially infer mechanisms for the rearrangements.

描述（由申请人提供）：在过去的二十年中，许多神经系统疾病的特征不是由基因内的编码区突变引起的，而是由于基因组的改变而表现出来的，这一点已经变得很明显。基因组疾病是一类由基因组重排而不是DNA序列的碱基对变化引起的疾病。一般来说，观察到两种主要类型的重排：复发性和非复发性基因组变化。复发性重排在不同患者中具有共同的大小;其中断点发生在“固定”基因组位置或断点簇区域。断点聚集在人类基因组的旁系同源区段（也称为低拷贝重复序列LCR或区段重复序列SD）中，其通过刺激和介导重排来促进非等位基因同源重组（NAHR）。非复发性重排在不同患者中可以具有不同的大小，但通常共享关键基因组内容物和/或基因所在的“最小重叠区域”（SRO）。由非复发性重排产生的基因组疾病为基因型/表型相关性的研究提供了独特的挑战。可变的大小和基因组含量以及可能与非复发性重排一起发生的复杂改变（例如，三重和倒位）的频繁共现进一步增加了在每个患者的临床表现的背景下解释基因组和基因变异的复杂性。我们假设，非经常性的重排可能发生的机制是不同的同源重组机制，我们的初步研究和最近的出版物，从第一年的刺激拨款强烈支持这一假设。此外，我们认为一些非复发性重排可能是由于特定的基因组结构特征导致对这种重排的易感性。我们计划调查这些假说，试图了解导致非复发性重排的机制的“规则”。我们将通过以下实验来研究这些假设：1）绘制重复重排、三重重排和复杂重排的断点。2)对经历重排的基因组区域进行生物信息学分析，和3）通过重组连接的直接DNA序列确定重组产物;即断点测序。4)通过全基因组阵列在三人组中研究标记基因型，所述三人组由患有疾病相关的从头复杂重排的患者及其未受影响的父母组成，以通过标记单倍型的分离进行表面链交换或潜在的模板转换。最后，我们将试图阐明基因，可能是重要的，这些重排过程中的个人基因组的全基因组测序的主题，或这些主题的父母，与多个从头CNV事件。通过这种方式，我们将确定重组的底物，深入了解相关区域的基因组结构，并可能推断重排的机制。