The Achilles’ heel of cancer survivors: fundamentals of accelerated cellular senescence

Recent improvements in cancer treatment have increased the lifespan of pediatric and adult cancer survivors. However, cancer treatments accelerate aging in survivors, which manifests clinically as the premature onset of chronic diseases, such as endocrinopathies, osteoporosis, cardiac dysfunction, subsequent cancers, and geriatric syndromes of frailty, among others. Therefore, cancer treatment–induced early aging accounts for significant morbidity, mortality, and health expenditures among cancer survivors. One major mechanism driving this accelerated aging is cellular senescence; cancer treatments induce cellular senescence in tumor cells and in normal, nontumor tissue, thereby helping mediate the onset of several chronic diseases. Studies on clinical monitoring and therapeutic targeting of cellular senescence have made considerable progress in recent years. Large-scale clinical trials are currently evaluating senotherapeutic drugs, which inhibit or eliminate senescent cells to ameliorate cancer treatment–related aging. In this article, we survey the recent literature on phenotypes and mechanisms of aging in cancer survivors and provide an up-to-date review of the major preclinical and translational evidence on cellular senescence as a mechanism of accelerated aging in cancer survivors, as well as insight into the potential of senotherapeutic drugs. However, only with time will the clinical effect of senotherapies on cancer survivors be visible.

Cancer survival times have increased annually owing to advances in early detection and treatment that prolong patient survival. However, increasing survivorship has underscored the observation that cancer survivors develop age-related diseases prematurely, which cause significant morbidity, health expenditures, and mortality. Many cancer survivors have been exposed to chemotherapy, radiotherapy, or both; despite eradicating cancer cells, these therapies also damage normal cells to accelerate biologic aging, such that a discrepancy exists between their biologic and chronologic age (1). Considerable data exist regarding the phenotypes of accelerated aging. However, mechanical and molecular uncertainties have limited the study of these manifestations in a clinical context. Our Review discusses accelerated aging phenotypes in cancer survivors and the cellular mechanisms underpinning these phenomena. We then discuss the translational evidence on how accelerated aging phenotypes, mainly related to senescence, are being targeted while highlighting areas of uncertainty for future research to address.