Dormancy, not apoptosis, restricts hematopoietic stem cell mutagenesis during aging

Genome instability and mutagenesis are hallmarks of aging, acting as drivers of some age-associated pathologies, including cancer1-3. Somatic cells engage multiple layers of protection against mutagenesis, including detoxification of genotoxic metabolites; repair of DNA damage; and elimination of cells which suffer excessive damage4-7. In this context, the intrinsic apoptotic pathway is engaged in response to activation of the DNA damage response (DDR) and is thought to play a major role in limiting accumulation of mutations, particularly in cells that act as an origin for cancer, such as somatic stem cells8,9. However, the dissection of the relative contribution of different protective mechanisms that restrict mutagenesis in such cells is confounded by the long time frame of experiments; relatively low mutation burden in non-malignant cells; and high variance across individuals due to differences in germ line and environment. Here we employ deep whole-genome sequencing (WGS) combined with extended time-course sampling from a range of experimental mouse models to study mutation acquisition in hematopoietic stem cells (HSCs) during aging. Having validated that murine HSCs recapitulate mutation acquisition patterns observed in aged human HSCs, we made the surprising discovery that apoptosis has a negligible role in restricting mutagenesis. Instead, we found that HSC dormancy inhibits mutagenesis during normal aging, with dormant HSCs from old mice demonstrating a mutation burden akin to their young counterparts. Importantly, breaking HSC dormancy via induction of sterile inflammation led to a dramatic acceleration in mutation rate, demonstrating that non-genotoxic environmental stimuli can modulate genome stability. These findings provide new insights into the correlation between inflammation and both aging and carcinogenesis.