Longitudinal change in mitochondrial heteroplasmy exhibits positive selection for deleterious variants.
Lieke M KuiperWen ShiJoost VerlouwYun Soo HongPascal ArpDaniela PuiuLinda BroerJiaqi XieCharles NewcombSteve RichKent TaylorJerome RotterJoel S BaderEliseo GuallarJoyce Bj van MeursDan E ArkingPublished in: medRxiv : the preprint server for health sciences (2024)
A common feature of human aging is the acquisition of somatic mutations, and mitochondria are particularly prone to mutation due to their inefficient DNA repair and close proximity to reactive oxygen species, leading to a state of mitochondrial DNA heteroplasmy. Cross-sectional studies have demonstrated that detection of heteroplasmy increases with participant age, a phenomenon that has been attributed to genetic drift. In this first large-scale longitudinal study, we measured heteroplasmy in two prospective cohorts (combined n=1405) at two timepoints (mean time between visits, 8.6 years), demonstrating that deleterious heteroplasmies were more likely to increase in variant allele fraction (VAF). We further demonstrated that increase in VAF was associated with increased risk of overall mortality. These results challenge the claim that somatic mtDNA mutations arise mainly due to genetic drift, instead demonstrating positive selection for predicted deleterious mutations at the cellular level, despite an negative impact on overall mortality.
Keyphrases
- mitochondrial dna
- copy number
- dna repair
- reactive oxygen species
- genome wide
- cross sectional
- dna methylation
- dna damage
- endothelial cells
- cardiovascular events
- machine learning
- oxidative stress
- risk factors
- cell death
- dna damage response
- deep learning
- type diabetes
- cardiovascular disease
- coronary artery disease
- gene expression
- label free
- loop mediated isothermal amplification
- induced pluripotent stem cells
- case control
- pluripotent stem cells