Biobank-driven genomic discovery yields new insight into atrial fibrillation biology

JB Nielsen, RB Thorolfsdottir, LG Fritsche, W Zhou… - Nature …, 2018 - nature.com
JB Nielsen, RB Thorolfsdottir, LG Fritsche, W Zhou, MW Skov, SE Graham, TJ Herron
Nature genetics, 2018nature.com
To identify genetic variation underlying atrial fibrillation, the most common cardiac
arrhythmia, we performed a genome-wide association study of> 1,000,000 people, including
60,620 atrial fibrillation cases and 970,216 controls. We identified 142 independent risk
variants at 111 loci and prioritized 151 functional candidate genes likely to be involved in
atrial fibrillation. Many of the identified risk variants fall near genes where more deleterious
mutations have been reported to cause serious heart defects in humans (GATA4, MYH6 …
Abstract
To identify genetic variation underlying atrial fibrillation, the most common cardiac arrhythmia, we performed a genome-wide association study of >1,000,000 people, including 60,620 atrial fibrillation cases and 970,216 controls. We identified 142 independent risk variants at 111 loci and prioritized 151 functional candidate genes likely to be involved in atrial fibrillation. Many of the identified risk variants fall near genes where more deleterious mutations have been reported to cause serious heart defects in humans (GATA4, MYH6, NKX2-5, PITX2, TBX5), or near genes important for striated muscle function and integrity (for example, CFL2, MYH7, PKP2, RBM20, SGCG, SSPN). Pathway and functional enrichment analyses also suggested that many of the putative atrial fibrillation genes act via cardiac structural remodeling, potentially in the form of an ‘atrial cardiomyopathy’, either during fetal heart development or as a response to stress in the adult heart.
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