Abstract
The ribosomal RNA gene, which consists of tandem repetitive arrays (rDNA repeat), is one of the most unstable regions in the genome. The rDNA repeat in the budding yeast is known to become unstable as the cell ages. However, it is unclear how the rDNA repeat changes in ageing mammalian cells. Using quantitative analyses, we identified age-dependent alterations in rDNA copy number and levels of methylation in mice. The degree of methylation and copy number of rDNA from bone marrow cells of 2-year-old mice were increased by comparison to 4-week-old mice in two mouse strains, BALB/cA and C57BL/6. Moreover, the level of pre-rRNA transcripts was reduced in older BALB/cA mice. We also identified many sequence variations among the repeats with two mutations being unique to old mice. These sequences were conserved in budding yeast and equivalent mutations shortened the yeast chronological lifespan. Our findings suggest that rDNA is also fragile in mammalian cells and alterations within this region have a profound effect on cellular function.
Author Summary The ribosomal RNA gene (rDNA) is one of the most unstable regions in the genome due to its tandem repetitive structure. rDNA copy number in the budding yeast increases and becomes unstable as the cell ages. It is speculated that the rDNA produces an “aging signal” inducing senescence and death. However, it is unclear how the rDNA repeat changes during the aging process in mammalian cells. In this study, we attempted to identify the age-dependent alteration of rDNA in mice. Using quantitative single cell analysis, we show that rDNA copy number increases in old mice bone marrow cells. By contrast, the level of ribosomal RNA production was reduced because of increased levels of DNA methylation that represses transcription. We also identified many sequence variations in the rDNA. Among them, three mutations were unique to old mice and two of them were found in the conserved region in budding yeast. We then established a yeast strain with the old mouse-specific mutations and found this shortened the lifespan of the cells. These findings suggest that rDNA is also fragile in mammalian cells and alteration to this region of the genome affects cellular senescence.
