2019
DOI: 10.2139/ssrn.3466338
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DNA Break-Induced Epigenetic Drift as a Cause of Mammalian Aging

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Cited by 28 publications
(48 citation statements)
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“…We can only begin to address this question after having first understood what epigenetic aging entails. As it stands, our knowledge in this area remains limited, but it is nevertheless clear that: (a) epigenetic aging is distinct from the process of cellular senescence and telomere attrition 41 , (b) several types of tissue stem cells are epigenetically younger than non-stem cells of the same tissue 42,43 , (c) a considerable number of age-related methylation sites, including some clock CpGs, are proximal to genes whose proteins are involved in the process of development 44 , (d) epigenetic clocks are associated with developmental timing 22,45 , and (e) relate to an epigenomic maintenance system 20,46 . Collectively, these features indicate that epigenetic aging is intimately associated with the process of development and homeostatic maintenance of the body post-maturity.…”
Section: Plasma Fraction Treatmentmentioning
confidence: 99%
“…We can only begin to address this question after having first understood what epigenetic aging entails. As it stands, our knowledge in this area remains limited, but it is nevertheless clear that: (a) epigenetic aging is distinct from the process of cellular senescence and telomere attrition 41 , (b) several types of tissue stem cells are epigenetically younger than non-stem cells of the same tissue 42,43 , (c) a considerable number of age-related methylation sites, including some clock CpGs, are proximal to genes whose proteins are involved in the process of development 44 , (d) epigenetic clocks are associated with developmental timing 22,45 , and (e) relate to an epigenomic maintenance system 20,46 . Collectively, these features indicate that epigenetic aging is intimately associated with the process of development and homeostatic maintenance of the body post-maturity.…”
Section: Plasma Fraction Treatmentmentioning
confidence: 99%
“…David Sinclair, Harvard, USA, showed that DSBs may drive age-dependent epigenetic alterations and loss of cellular identity. Using a transgenic mouse system for inducible creation of DSBs, he revealed that loss of epigenetic structures, an accumulation of epigenetic noise and increased predicted DNA methylation changes increase with age and DNA damage [42,43]. Importantly, the introduction of an engineered vector expressing Yamanaka transcription factors, excluding c-Myc, regenerated axons after optic nerve crush injury and restored vision in old mice [44].…”
Section: Genome Maintenance In Aging and Longevitymentioning
confidence: 99%
“…Nevertheless, both can be linked because DNA double‐strand breaks induce epigenetic drift that in turn produces aging phenotypes. [ 47 ] Thus, increased epigenomic variation could occur with age because of defects in restoration of the epigenome after DNA replication or repair that result in the progressive alteration of methylation and histone modification patterns. This suggests that DNA damage is a conserved cause of aging.…”
Section: Increased Cell‐to‐cell Gene Expression Heterogeneity Is Seenmentioning
confidence: 99%