Platelet Mitochondrial Epigenetics: New CVD Markers of Particle and Metal Effects

血小板线粒体表观遗传学：粒子和金属效应的新 CVD 标记

基本信息

批准号：
8637521
负责人：
Hyang-Min Byun
金额：
$ 28.26万
依托单位：
HARVARD SCHOOL OF PUBLIC HEALTH
依托单位国家：
美国
项目类别：
财政年份：
2014
资助国家：
美国
起止时间：
2014-01-17 至 2015-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8637521
关键词：
8-Oxo-2&apos -Deoxyguanosine Accounting Address Age Age-Years Aging Air Pollutants Air Pollution American Atherosclerosis Biochemical Biological Markers Blood Blood Cells Blood Platelets Carbon Black Cardiovascular Diseases Cause of Death Cells Cessation of life Chronic DNA DNA Damage DNA Markers DNA Methylation DNA Sequence Data Development Diagnostic Disease Marker Disease Pathway Disease-Free Survival Elderly Elderly man Environmental Air Pollutants Environmental Exposure Epidemiologic Studies Epidemiology Epigenetic Process Etiology Event Exposure to Funding Future Genes Goals Healthcare Heavy Metals Human Human body Individual Inflammation Lead Leukocytes Link Measures Mediating Mediation Mercury Metal exposure Metals Methylation Mitochondria Mitochondrial DNA Modeling Modification Molecular Morbidity - disease rate Myocardial Infarction Oxidative Stress Participant Particulate Matter Pattern Persons Plasma Platelet Count measurement Population Population Heterogeneity Prevention Preventive Process Production Protocols documentation Research Resources Risk Role Sampling Staging Stroke Symptoms Testing Thrombosis Time TimeLine Tissues Toxicant exposure United States age related cardiovascular disorder risk care burden cell type clinical application cohort cost cost effective follow-up high risk human tissue improved inflammatory marker lead exposure mitochondrial dysfunction novel oxidation oxidative damage particle programs prospective public health relevance response tool toxic metal trafficking

项目摘要

DESCRIPTION (provided by applicant): Biomarkers are cellular, biochemical, or molecular alterations that can be easily and non-invasively measured in human tissues and are directly or indirectly involved in the pathway of disease. Cardiovascular disease (CVD) is the leading cause of death in the United States accounting for 800,000 deaths every year. Both short- and long-term exposure to air pollution/toxic metals has been consistently associated with CVD morbidity and death in epidemiologic studies. Platelets contribute to the development of both atherosclerosis and arterial thrombosis, which are primary contributing events leading to CVD. Increased platelet counts have been suggested to mediate particulate matter (PM) effects. Platelets are anucleate, but mitochondrial DNA (mtDNA) can be easily isolated from plasma platelets. Mitochondria are highly sensitive to PM-related oxidation and, most importantly, platelets are critically dependent on energy production in mitochondria. We hypothesize that air pollutants and metals exposure may cause alteration in platelet mitochondrial DNA methylation (mtDNA) in response to exposure-induced systemic oxidation/inflammation. Platelet mtDNA methylation changes may lead to, or at a minimum reflect mitochondrial dysfunction participating directly or indirectly to the paths linking toxic exposures to CVD risk. We propose t test these hypotheses using data and biospecimens from the Normative Aging Study (NAS), a large prospective cohort of aging individuals. We have modified and adapted protocols to isolate mtDNA from plasma platelets, and successfully tested our highly time- and cost-effective approach. Plasma platelets from 700 participants will be measured at two time points separated by 4 years for mtDNA oxidative damage (8-oxo-dG), mitochondrial global content of both standard DNA methylation (5-mC) and the emerging hydroxymethylation (5-OH-mC) mark, and locus-specific methylation in a comprehensive panel of mtDNA sequences. We will determine the effects of air pollution and metals on mtDNA biomarkers (Aim 1); evaluate further association of mtDNA biomarkers with CVD risk (Aim 2); and conduct an exploratory aim (Aim 3) to determine via mediation analysis whether platelet mtDNA changes are directly or indirectly on the paths linking toxic exposures to oxidation/inflammation markers, and ultimately to CVD risk. The proposed study will be the first to characterize mechanisms in platelet mtDNA methylation related to CVD risk. The project's focus on platelets, a single pure cell population with critical roles in CVD etiology will provide ease of interpretation of epigenetic findings and thus overcome the major limitation of current epigenetic studies in large human population, which have been hampered by the use of mixed cell populations such as white blood cells or buccal cells. Because platelets can be inexpensively and non- invasively isolated from plasma, our study has high potential to generate novel risk and diagnostic biomarkers of future CVD. If we observed the hypothesized associations, we will seek funding to expand this line of research in large-scale studies in diverse populations with high risk of CVD.

描述（由申请人提供）：生物标志物是细胞，生化或分子改变，可以在人体组织中易于和无创测量，并直接或间接参与疾病途径。心血管疾病（CVD）是美国死亡的主要原因，每年死亡80万人。在流行病学研究中，短期和长期暴露于空气污染/有毒金属一直与CVD发病率和死亡有关。血小板有助于动脉粥样硬化和动脉血栓形成的发展，这是导致CVD的主要事件。已经提出了增加的血小板计数来介导颗粒物（PM）效应。血小板是无核的，但是线粒体DNA（mtDNA）可以很容易地从血浆血小板中分离出来。线粒体对与PM相关的氧化高度敏感，最重要的是，血小板严重取决于线粒体的能源产生。我们假设空气污染物和金属暴露可能会导致血小板线粒体DNA甲基化（mtDNA）的改变，这是对暴露诱导的全身氧化/炎症的响应。血小板mtDNA甲基化变化可能导致或最少反映线粒体功能障碍，直接或间接地与将有毒暴露与CVD风险联系起来的路径。我们提出了t检验这些假设的使用数据和生物测量的规范性老化研究（NAS），这是一个大量的老龄化个体的前瞻性队列。我们已经修改了调整的方案，以将mtDNA与血浆血小板分离，并成功地测试了我们的高度时间和成本效益的方法。将在两个时间点测量来自700名参与者的血浆血小板，用于MTDNA氧化损伤（8-oxo-DG），标准DNA甲基化（5-MC）的线粒体全球含量以及新兴的羟甲甲基化（5-OH-HOH-MC）标记（5-OH-MC）标记和位点 - 特异性甲基化的特种甲基化。我们将确定空气污染和金属对mtDNA生物标志物的影响（AIM 1）；评估MTDNA生物标志物与CVD风险的进一步关联（AIM 2）；并进行探索性目的（AIM 3）通过中介分析确定血小板mtDNA是否直接或间接地在将有毒暴露与氧化/炎症标记的路径上直接或间接变化，最终是与CVD风险。拟议的研究将是第一个表征与CVD风险相关的血小板mtDNA甲基化机制的表征。该项目对血小板的关注，在CVD病因中具有关键作用的单个纯细胞种群将易于解释表观遗传发现，从而克服了大人群中当前的表观遗传学研究的主要限制，这些局限性因使用混合细胞种群（如白血细胞或肿瘤细胞）而受到阻碍。由于血小板可以从血浆中廉价和非侵入性地分离，因此我们的研究具有产生未来CVD的新型风险和诊断生物标志物的很高潜力。如果我们观察到假设的关联，我们将寻求资金来扩大在CVD高风险的不同人群中的大规模研究中的这一研究。