Determinants of accelerated metabolomic and epigenetic aging in a UK cohort.
Oliver RobinsonMarc Chadeau HyamIbrahim KaramanRui Climaco PintoMika Ala-KorpelaEvangelos HandakasGiovanni FioritoHe GaoAndy HeardMarjo-Riitta JarvelinMatthew LewisRaha PazokiSilvia PolidoroIoanna TzoulakiMatthias WielscherPaul ElliottPaolo VineisPublished in: Aging cell (2020)
Markers of biological aging have potential utility in primary care and public health. We developed a model of age based on untargeted metabolic profiling across multiple platforms, including nuclear magnetic resonance spectroscopy and liquid chromatography-mass spectrometry in urine and serum, within a large sample (N = 2,239) from the UK Airwave cohort. We validated a subset of model predictors in a Finnish cohort including repeat measurements from 2,144 individuals. We investigated the determinants of accelerated aging, including lifestyle and psychological risk factors for premature mortality. The metabolomic age model was well correlated with chronological age (mean r = .86 across independent test sets). Increased metabolomic age acceleration (mAA) was associated after false discovery rate (FDR) correction with overweight/obesity, diabetes, heavy alcohol use and depression. DNA methylation age acceleration measures were uncorrelated with mAA. Increased DNA methylation phenotypic age acceleration (N = 1,110) was associated after FDR correction with heavy alcohol use, hypertension and low income. In conclusion, metabolomics is a promising approach for the assessment of biological age and appears complementary to established epigenetic clocks.
Keyphrases
- dna methylation
- mass spectrometry
- public health
- liquid chromatography
- primary care
- gene expression
- weight loss
- cardiovascular disease
- blood pressure
- genome wide
- physical activity
- insulin resistance
- depressive symptoms
- cross sectional
- coronary artery disease
- body mass index
- risk assessment
- ms ms
- glycemic control
- risk factors
- global health