Bayesian reassessment of the epigenetic architecture of complex traits

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作者
Daniel Trejo Banos
Daniel L. McCartney
Marion Patxot
Lucas Anchieri
Thomas Battram
Colette Christiansen
Ricardo Costeira
Rosie M. Walker
Stewart W. Morris
Archie Campbell
Qian Zhang
David J. Porteous
Allan F. McRae
Naomi R. Wray
Peter M. Visscher
Chris S. Haley
Kathryn L. Evans
Ian J. Deary
Andrew M. McIntosh
Gibran Hemani
Jordana T. Bell
Riccardo E. Marioni
Matthew R. Robinson
机构
[1] University of Lausanne,Department of Computational Biology
[2] Institute of Genetics and Molecular Medicine,Centre for Genomic and Experimental Medicine
[3] University of Edinburgh,MRC Integrative Epidemiology Unit
[4] University of Bristol,Population Health Sciences
[5] Bristol Medical School,Department of Twin Research and Genetic Epidemiology
[6] University of Bristol,Institute for Molecular Bioscience
[7] King’s College London,MRC Human Genetics Unit
[8] University of Queensland,Centre for Cognitive Ageing and Cognitive Epidemiology
[9] Institute of Genetics and Molecular Medicine,Department of Psychology
[10] University of Edinburgh,Division of Psychiatry
[11] University of Edinburgh,undefined
[12] University of Edinburgh,undefined
[13] University of Edinburgh,undefined
[14] Royal Edinburgh Hospital,undefined
[15] Institute of Science and Technology Austria,undefined
来源
Nature Communications | / 11卷
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摘要
Linking epigenetic marks to clinical outcomes improves insight into molecular processes, disease prediction, and therapeutic target identification. Here, a statistical approach is presented to infer the epigenetic architecture of complex disease, determine the variation captured by epigenetic effects, and estimate phenotype-epigenetic probe associations jointly. Implicitly adjusting for probe correlations, data structure (cell-count or relatedness), and single-nucleotide polymorphism (SNP) marker effects, improves association estimates and in 9,448 individuals, 75.7% (95% CI 71.70–79.3) of body mass index (BMI) variation and 45.6% (95% CI 37.3–51.9) of cigarette consumption variation was captured by whole blood methylation array data. Pathway-linked probes of blood cholesterol, lipid transport and sterol metabolism for BMI, and xenobiotic stimuli response for smoking, showed >1.5 times larger associations with >95% posterior inclusion probability. Prediction accuracy improved by 28.7% for BMI and 10.2% for smoking over a LASSO model, with age-, and tissue-specificity, implying associations are a phenotypic consequence rather than causal.
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