Genetic architecture of spatial electrical biomarkers for cardiac arrhythmia and relationship with cardiovascular disease.
William J YoungJeffrey HaesslerJan-Walter BenjaminsLinda RepettoJie YaoAaron IsaacsAndrew R HarperJulia RamírezSophie GarnierStefan van DuijvenbodenAntoine R BaldassariMaria Pina ConcasThuyVy DuongLuisa FocoJonas L IsaksenHao MeiRaymond NoordamCasia NursyifaAnne RichmondMeddly L SantolallaColleen M SitlaniNegin SoroushSébastien ThériaultStella TrompetStefanie AeschbacherFariba AhmadizarAlvaro AlonsoJennifer A BrodyArchie I CampbellAdolfo CorreaDawood DarbarAntonio De LucaJean François DeleuzeChristina EllervikChristian FuchsbergerAnuj GoelChristopher GraceXiuqing GuoTorben HansenSusan R HeckbertRebecca D JacksonJan A KorsMaria Fernanda Lima-CostaAllan LinnebergPeter W MacfarlaneAlanna C MorrisonPau NavarroDavid J PorteousPeter Paul PramstallerAlexander P ReinerLorenz RischUlrich SchottenXia ShenGianfranco SinagraElsayed Z SolimanMonika StollEduardo Tarazona-SantosAndrew TinkerKaterina TrajanoskaEric VillardHelen R WarrenEric A WhitselKerri L WigginsDan E ArkingChristy L AveryDavid ConenGiorgia GirottoNiels GrarupCaroline HaywardJohan Wouter JukemaDennis O Mook-KanamoriMorten Salling OlesenSandosh PadmanabhanBruce M PsatyCristian PattaroAntonio Luiz Pinho RibeiroJerome I RotterBruno H StrickerPim van der HarstCornelia M Van DuijnNiek VerweijJames G WilsonMichele OriniPhilippe CharronHugh C WatkinsCharles KooperbergHenry J LinJames F WilsonJørgen Kim KantersNona SotoodehniaBorbala MifsudPier D LambiaseLarisa G TereshchenkoPatricia B MunroePublished in: Nature communications (2023)
The 3-dimensional spatial and 2-dimensional frontal QRS-T angles are measures derived from the vectorcardiogram. They are independent risk predictors for arrhythmia, but the underlying biology is unknown. Using multi-ancestry genome-wide association studies we identify 61 (58 previously unreported) loci for the spatial QRS-T angle (N = 118,780) and 11 for the frontal QRS-T angle (N = 159,715). Seven out of the 61 spatial QRS-T angle loci have not been reported for other electrocardiographic measures. Enrichments are observed in pathways related to cardiac and vascular development, muscle contraction, and hypertrophy. Pairwise genome-wide association studies with classical ECG traits identify shared genetic influences with PR interval and QRS duration. Phenome-wide scanning indicate associations with atrial fibrillation, atrioventricular block and arterial embolism and genetically determined QRS-T angle measures are associated with fascicular and bundle branch block (and also atrioventricular block for the frontal QRS-T angle). We identify potential biology involved in the QRS-T angle and their genetic relationships with cardiovascular traits and diseases, may inform future research and risk prediction.
Keyphrases
- genome wide association
- cardiac resynchronization therapy
- genome wide
- left ventricular
- high resolution
- cardiovascular disease
- catheter ablation
- atrial fibrillation
- heart failure
- working memory
- functional connectivity
- dna methylation
- type diabetes
- genome wide association study
- metabolic syndrome
- mitral valve
- drug induced
- venous thromboembolism
- percutaneous coronary intervention
- coronary artery disease
- heart rate variability
- smooth muscle