Polygenic interactions with environmental exposures in blood pressure regulation: the HUNT study
Øvretveit, Karsten; Ingeström, Emma Maria Lovisa; Spitieris, Michail; Tragante, Vinicius; Thomas, Laurent Francois; Steinsland, Ingelin; Brumpton, Ben Michael; Gudbjartsson, Daníel Fannar; Hólm, Hilma; Stefánsson, Kári; Wisløff, Ulrik; Hveem, Kristian
Journal article, Peer reviewed
Published version
Date
2024Metadata
Show full item recordCollections
Original version
Journal of the American Heart Association (JAHA). 2024, 1-10. 10.1161/JAHA.123.034612Abstract
Background: The essential hypertension phenotype results from an interplay between genetic and environmental factors. The influence of lifestyle exposures such as excess adiposity, alcohol consumption, tobacco use, diet, and activity patterns on blood pressure (BP) is well established. Additionally, polygenic risk scores for BP traits are associated with clinically significant phenotypic variation. However, interactions between genetic and environmental risk factors in hypertension morbidity and mortality are poorly characterized.
Methods and Results: We used genotype and phenotype data from up to 49 234 participants from the HUNT (Trøndelag Health Study) to model gene–environment interactions between genome‐wide polygenic risk scores for systolic BP and diastolic BP and 125 environmental exposures. Among the 125 environmental exposures assessed, 108 and 100 were independently associated with SBP and DBP, respectively. Of these, 12 interactions were identified for genome‐wide PRSs for systolic BP and 4 for genome‐wide polygenic risk scores for diastolic BP, 2 of which were overlapping (P < 2 × 10−4). We found evidence for gene‐dependent influence of lifestyle factors such as cardiorespiratory fitness, dietary patterns, and tobacco exposure, as well as biomarkers such as serum cholesterol, creatinine, and alkaline phosphatase on BP.
Conclusions: Individuals that are genetically susceptible to high BP may be more vulnerable to common acquired risk factors for hypertension, but these effects appear to be modifiable. The gene‐dependent influence of several common acquired risk factors indicates the potential of genetic data combined with lifestyle assessments in risk stratification, and gene–environment‐informed risk modeling in the prevention and management of hypertension.