Genome-wide mapping and integrative analysis of DNA 6mA methylome in human AD brain

人类 AD 大脑 DNA 6mA 甲基化组的全基因组作图和综合分析

• 批准号: 10404653
• 负责人: DAVID ALAN BENNETT
• 金额: $ 71.38万
• 依托单位: UNIVERSITY OF FLORIDA
• 依托单位国家: 美国
• 财政年份: 2019
• 资助国家: 美国
• 起止时间: 2019-09-01 至 2024-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10404653
• 关键词: 3-Dimensional; Adenine; Affect; Aging; Alzheimer' s Disease; Alzheimer' s disease brain; Alzheimer' s disease pathology; Alzheimer' s disease patient; Amyloid; Attention; Autopsy; Bioinformatics; Biological; Biological Process; Brain; Brain Mapping; Candidate Disease Gene; Chemicals; Clinical; Communities; Cytosine; DNA; DNA Methylation; DNA Modification Process; DNA analysis; Data; Data Set; Dementia; Development; Dimensions; Disease; Elderly; Epigenetic Process; Etiology; Exons; Freezing; Gene Expression; Genes; Genetic; Genetic Variation; Genomics; Goals; Histone Acetylation; Human; Intercistronic Region; Introns; Joints; Lead; Link; Maps; Measures; Memory; Mental Depression; Meta-Analysis; Methylation; MicroRNAs; Modification; Molecular; Molecular Target; Mus; Neurofibrillary Tangles; Organoids; Participant; Pathogenesis; Pathway interactions; Pattern; Persons; Phenotype; Play; Population; Positioning Attribute; Prefrontal Cortex; Prosencephalon; Quantitative Trait Loci; Research; Role; Sampling; Senile Plaques; Site; Stress; System; Testing; Tissue Sample; Tissues; Validation; Variant; Work; aging brain; base; brain tissue; cell type; cohort; design; effective therapy; epigenetic marker; epigenetic regulation; frontier; genetic epidemiology; genome wide association study; genome-wide; genomic locus; induced pluripotent stem cell; innovation; insight; knock-down; mammalian genome; methylation pattern; methylome; multidisciplinary; multiple omics; neuropathology; novel; novel diagnostics; novel therapeutic intervention; novel therapeutics; overexpression; population based; promoter; religious order study; tool; transcriptome; transcriptome sequencing

Project Summary Alzheimer’s disease (AD) is the most common form of dementia among older people with no cure or effective treatment. A thorough understanding of its molecular mechanisms is required for discovering novel diagnostic and therapeutic strategies against AD. Chemical modifications of DNA such as methylation play critical roles in regulating gene expression and many other key biological processes, and altered DNA methylation pattern has been implicated in brain aging and AD. While much attention has focused on DNA methylation at the fifth position on cytosine (5mC), recent research identified a new form of DNA modification at the sixth position on adenine (6mA) in mammalian brains. However, little is known about its presence, genomic distribution, and possible functions in human brain and relevance to AD. Our preliminary data in mouse and human brain indicated that 6mA is dynamically responsive to environmental stress and accumulates in human AD brain. Our central hypothesis is that altered signature of 6mA modification is causally associated with AD neuropathology. The objectives of this project are to generate the first detailed map of brain 6mA methylome and identify causative genes harboring aberrant 6mA alterations associated with quantitative neuropathological measures for early features of AD pathology (e.g., amyloid plaques, neurofibrillary tangles). To achieve this, we propose three specific aims: (1) Genome-wide mapping of brain DNA 6mA methylome to identify differentially methylated genes/regions harboring altered 6mA sites (D6AMRs) associated with AD pathology in 1,200 postmortem brain tissue samples collected by two large, community-based population cohorts of aging and dementia. (2) Integrated multiomics analysis to elucidate the potential mechanistic role of 6mA alteration in AD pathology; and (3) Functionally validation of top-ranked candidate genes in 3D brain organoids derived from human iPSCs. This innovative project leverages the wealth of deep clinical and neuropathological phenotypes along with rich omics data including genetic (GWAS, WGS), epigenetic (5mC, 5hmC, 6mA, H3K9Ac), and transcriptome (RNA-seq) profiled on the same prefrontal cortex, and will provide unprecedented opportunities to uncover novel molecular mechanisms implicated in AD pathology. Our proposal brings together an exceptionally strong and unique multidisciplinary team with complementary expertise in genetic epidemiology, statistical genetics, bioinformatics, molecular and neuroepigenetics, and Alzheimer’s research. The work proposed represents the frontier in the interface between AD and omics research. Findings of this study will provide novel mechanistic insight into AD pathogenesis, and are likely to discover new molecular targets with important clinical and translational implications.

项目概要 阿尔茨海默病 (AD) 是老年人中最常见的痴呆症，无法治愈或有效 需要彻底了解其分子机制才能发现新的诊断方法。 DNA 的化学修饰（例如甲基化）在 AD 中发挥着关键作用。 调节基因表达和许多其他关键生物过程，DNA甲基化模式具有 第五，DNA甲基化与大脑衰老和AD有关。 胞嘧啶 (5mC) 上的位置，最近的研究在胞嘧啶 (5mC) 的第六位上发现了一种新形式的 DNA 修饰 哺乳动物大脑中的腺嘌呤 (6mA) 然而，人们对其存在、基因组分布和作用知之甚少。 人类大脑中可能的功能以及与 AD 的相关性我们在小鼠和人类大脑中的初步数据。 表明 6mA 对环境压力动态响应并在人类 AD 大脑中积累。 我们的中心假设是 6mA 修饰的改变特征与 AD 存在因果关系 该项目的目标是生成大脑 6mA 甲基化组的第一个详细图谱。 并识别含有与定量神经病理学相关的异常 6mA 改变的致病基因 针对 AD 病理学早期特征（例如淀粉样蛋白斑、神经原纤维缠结）的措施。 我们提出了三个具体目标：（1）大脑 DNA 6mA 甲基化组的全基因组图谱，以识别 差异甲基化基因/区域含有与 AD 病理相关的改变的 6mA 位点 (D6AMR) 由两个大型社区老龄人口队列收集的 1,200 个死后脑组织样本 (2) 综合多组学分析阐明 6mA 改变的潜在机制作用。 AD 病理学；(3) 3D 脑类器官中排名靠前的候选基因的功能验证 该创新项目利用了丰富的深度临床和神经病理学知识。 表型以及丰富的组学数据，包括遗传（GWAS、WGS）、表观遗传（5mC、5hmC、6mA、 H3K9Ac）和转录组（RNA-seq）在同一前额皮质上进行分析，并将提供前所未有的 我们的提议带来了发现与 AD 病理学相关的新分子机制的机会。 汇集了一支异常强大且独特的多学科团队，在遗传领域具有互补的专业知识 流行病学、统计遗传学、生物信息学、分子和神经表观遗传学以及阿尔茨海默病研究。 所提出的工作代表了 AD 和组学研究之间的前沿。 研究将为 AD 发病机制提供新的机制见解，并可能发现新的分子 具有重要临床和转化意义的目标。