Comprehensive genetic analysis of the human lipidome identifies loci associated with lipid homeostasis with links to coronary artery disease.
Cadby G., Giles C., Melton PE., Huynh K., Mellett NA., Duong T., Nguyen A., Cinel M., Smith A., Olshansky G., Wang T., Brozynska M., Inouye M., McCarthy NS., Ariff A., Hung J., Hui J., Beilby J., Dubé M-P., Watts GF., Shah S., Wray NR., Lim WLF., Chatterjee P., Martins I., Laws SM., Porter T., Vacher M., Bush AI., Rowe CC., Villemagne VL., Ames D., Masters CL., Taddei K., Arnold M., Kastenmüller G., Nho K., Saykin AJ., Han X., Kaddurah-Daouk R., Martins RN., Blangero J., Meikle PJ., Moses EK.
We integrated lipidomics and genomics to unravel the genetic architecture of lipid metabolism and identify genetic variants associated with lipid species putatively in the mechanistic pathway for coronary artery disease (CAD). We quantified 596 lipid species in serum from 4,492 individuals from the Busselton Health Study. The discovery GWAS identified 3,361 independent lipid-loci associations, involving 667 genomic regions (479 previously unreported), with validation in two independent cohorts. A meta-analysis revealed an additional 70 independent genomic regions associated with lipid species. We identified 134 lipid endophenotypes for CAD associated with 186 genomic loci. Associations between independent lipid-loci with coronary atherosclerosis were assessed in ∼456,000 individuals from the UK Biobank. Of the 53 lipid-loci that showed evidence of association (P