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Paper Details

Mitochondrial DNA copy number can influence mortality and cardiovascular disease via methylation of nuclear DNA CpGs.
Genome Med
57
2020
-CN, Atherosclerosis, CN, Cas9, CpGs, Mitochondrial, Mitochondrial DNA, TFAM, aging-related diseases, cardiovascular disease, coronary heart disease, genes, human, mtDNA, nDNA, nuclear DNA, nuclear DNA CpGs, nuclear gene, participants
Author NameAffiliation
Megan L GroveSchool of Public Health, University of Texas Health Science Center at Houston
Jennifer A BrodyCardiovascular Health Research Unit, University of Washington
James S FloydCardiovascular Health Research Unit, University of Washington
James S FloydCardiovascular Health Research Unit, University of Washington
Traci M BartzCardiovascular Health Research Unit, University of Washington
Traci M BartzUniversity of Washington
Kent D TaylorInstitute for Translational Genomics and Population Sciences, Los Angeles BioMedical Research Institute at Harbor-university of california los angeles Medical Center
Adrienne TinDepartment of Epidemiology and the Welch Center for Prevention, Epidemiology and Clinical Research, Johns Hopkins Bloomberg School of Public Health
Josef CoreshDepartment of Epidemiology and the Welch Center for Prevention, Epidemiology and Clinical Research, Johns Hopkins Bloomberg School of Public Health
James S PankowSchool of Public Health, University of Minnesota
Myriam FornageSchool of Public Health, University of Texas Health Science Center at Houston
Myriam FornageBrown Foundation Institute of Molecular Medicine, McGovern Medical School, University of Texas Health Science Center at Houston
Brian O'RourkeJohns Hopkins University School of Medicine
Nathan PankratzUniversity of Minnesota School of Medicine
Nathan PankratzUniversity of Minnesota School of Medicine
Chunyu LiuBoston University School of Public Health
Chunyu LiuBoston University School of Public Health
Daniel Levy
Daniel Levyand Blood Institute, National Institutes of Health
Daniel Levy
Daniel Levyand Blood Institute, National Institutes of Health
Nona SotoodehniaCardiovascular Health Research Unit, University of Washington
Nona SotoodehniaCardiovascular Health Research Unit, University of Washington
Eric BoerwinkleSchool of Public Health, University of Texas Health Science Center at Houston
Eric BoerwinkleSchool of Public Health, University of Texas Health Science Center at Houston
Dan E ArkingJohns Hopkins University School of Medicine
Dan E ArkingJohns Hopkins University School of Medicine
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Datasets

KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink
KEGGKyoto encyclopedia of genes and genomes: databases on genes, proteins, and metabolic pathwaysLink