Abstract
DNA damage causally contributes to aging and cancer. Congenital defects in nucleotide excision repair (NER) lead to distinct cancer-prone and premature aging syndromes. The genetics of NER mutations have provided important insights into the distinct consequences of genome instability. Recent work in mice and C. elegans has shed new light on the mechanisms through which developing and aging animals respond to persistent DNA damage. The various NER mouse mutants have served as important disease models for Xeroderma pigmentosum (XP), Cockayne syndrome (CS), and trichothiodystrophy (TTD), while the traceable genetics of C. elegans have allowed the mechanistic delineation of the distinct outcomes of genome instability in metazoan development and aging. Intriguingly, highly conserved longevity assurance mechanisms respond to transcription-blocking DNA lesions in mammals as well as in worms and counteract the detrimental consequences of persistent DNA damage. The insulin-like growth factor signaling (IIS) effector transcription factor DAF-16 could indeed overcome DNA damage-driven developmental growth delay and functional deterioration even when DNA damage persists. Longevity assurance mechanisms might thus delay DNA damage-driven aging by raising the threshold when accumulating DNA damage becomes detrimental for physiological tissue functioning.
Highlights
Aging is characterized by the declining functioning of tissues and organs and the steadily increased risk of succumbing to aging-associated diseases
The importance of genome maintenance for withstanding the aging process has become evident in a variety of genetic disorders that are caused by heritable mutations in DNA repair genes and are manifested in premature aging in a multitude of tissues [2]
Human syndromes that are caused by mutations in nucleotide excision repair (NER) genes are rare genetic disorders that can have debilitating consequences
Summary
Aging is characterized by the declining functioning of tissues and organs and the steadily increased risk of succumbing to aging-associated diseases. Understanding the causes of aging and the mechanisms that determine the aging process remain major scientific challenges, in global societies that are faced by the demographic change with increasing burdens of aging-associated diseases. DNA repair processes were already formed to allow the maintenance of species. The importance of genome maintenance for withstanding the aging process has become evident in a variety of genetic disorders that are caused by heritable mutations in DNA repair genes and are manifested in premature aging in a multitude of tissues [2]. When DNA or RNA polymerases are unable to bypass DNA lesions, cells might enter cellular senescence or even undergo programmed cell death, leading to loss of tissue integrity and reduced regenerative capacities of stem cell compartments
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