Acquisition of Oxidative DNA Damage during Senescence: The First Step toward Carcinogenesis?

doi:10.1196/annals.1404.010

As a result of time and cumulative divisions in vitro and invivo, normal cells enter an irreversible nonproliferative statetermed replicative or cellular senescence that is thought tocontribute to organism aging. Both telomere shortening and cumulativeoxidative damage were shown to contribute to senescence, probablyacting at different degrees according to proliferation index,cell type, or environment. Because of its associated cohortof damages and irreversible cell-cycle arrest induced by shortenedtelomeres, senescence is commonly considered as a tumor-suppressormechanism that stops the proliferation of genetically alteredcells (i.e., potentially cancerous). However, the incidenceof the most frequent cancers in humans, carcinomas, exponentiallyincreases with age; the phenotypes of progeroid syndromes areoften associated with an increase in tumor incidence, and inverselywhen aging is delayed by caloric restriction, the cancer incidencedecreases. How can this positive link between aging and tumorigenesisbe explained if senescence is a tumor-suppressor mechanism?The present article considers data and arguments supportinga protumoral role of senescence. We focus on the importanceof the oxidative damage that targets DNA during senescence.Indeed, because of its mutagenic effects, oxidative damage couldaffect oncogenes and/or tumor-suppressor genes in some senescentcells, hence promoting their evolution toward initiated cancercells. This mechanism could be particularly relevant for age-associatedcarcinomas because senescence in epithelial cells is drivenmore by oxidative stress than by telomere shortening.

Part IV. DNA Repair and Aging

The First Step toward Carcinogenesis?