Abstract
Replication Stress (RS) is a type of DNA damage generated at the replication fork, characterized by single-stranded DNA (ssDNA) accumulation, and which can be caused by a variety of factors. Previous studies have reported elevated RS levels in aged cells. In addition, mouse models with a deficient RS response show accelerated aging. However, the relevance of endogenous or physiological RS, compared to other sources of genomic instability, for the normal onset of aging is unknown. We have performed long term survival studies of transgenic mice with extra copies of the Chk1 and/or Rrm2 genes, which we previously showed extend the lifespan of a progeroid ATR-hypomorphic model suffering from high levels of RS. In contrast to their effect in the context of progeria, the lifespan of Chk1, Rrm2 and Chk1/Rrm2 transgenic mice was similar to WT littermates in physiological settings. Most mice studied died due to tumors -mainly lymphomas- irrespective of their genetic background. Interestingly, a higher but not statistically significant percentage of transgenic mice developed tumors compared to WT mice. Our results indicate that supraphysiological protection from RS does not extend lifespan, indicating that RS may not be a relevant source of genomic instability on the onset of normal aging.
Highlights
Researchers have investigated the process of aging: a decline in health over time, which is generally considered to be due to an accumulation of cellular damage [1, 2]
In order to investigate the effect of Replication Stress (RS) on lifespan, we used the Chk1Tg and Rrm2Tg mouse models previously generated in our laboratory [24, 25]
We aimed to determine whether overexpression of Chk1 and/or Rrm2 could extend mammalian lifespan by utilizing transgenic mouse models carrying extra copies of the Chk1 and Rrm2 genes
Summary
Researchers have investigated the process of aging: a decline in health over time, which is generally considered to be due to an accumulation of cellular damage [1, 2] This cellular damage has different causes, but genomic instability is considered one of the main factors that contribute to cellular aging [3]. Several mouse models have confirmed that mutations in DNA repair proteins lead to accelerated aging These mice exhibit accelerated aging and agingrelated phenotypes such as alopecia, grey hair, osteoporosis, cachexia, neurological abnormalities, retinal degeneration and a predisposition to a wide variety of cancers [5, 7,8,9,10,11,12]. Which types of DNA damage play a central role in the context of aging is still unknown
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