Cellular senescence can be triggered by telomere shortening as well as a variety of stresses and signaling imbalances. We used multiparameter single-cell detection methods to investigate upstream signaling pathways and ensuing cell cycle checkpoint responses in human fibroblasts. Telomeric foci containing multiple DNA damage response factors were assembled in a subset of senescent cells and signaled through ATM to p53, upregulating p21 and causing G1 phase arrest. Inhibition of ATM expression or activity resulted in cell cycle reentry, indicating that stable arrest requires continuous signaling. ATR kinase appears to play a minor role in normal cells but in the absence of ATM elicited a delayed G2 phase arrest. These pathways do not affect expression of p16, which was upregulated in a telomere- and DNA damage-independent manner in a subset of cells. Distinct senescence programs can thus progress in parallel, resulting in mosaic cultures as well as individual cells responding to multiple signals.
The aging of organisms is characterized by a gradual functional decline of all organ systems. Mammalian somatic cells in culture display a limited proliferative life span, at the end of which they undergo an irreversible cell cycle arrest known as replicative senescence. Whether cellular senescence contributes to organismal aging has been controversial. We investigated telomere dysfunction, a recently discovered biomarker of cellular senescence, and found that the number of senescent fibroblasts increases exponentially in the skin of aging baboons, reaching >15% of all cells in very old individuals. In addition, the same cells contain activated ataxia-telangiectasia mutated kinase and heterochromatinized nuclei, confirming their senescent status.
The DNA damage response (DDR) arrests cell-cycle progression until damage is removed. DNA damage-induced cellular senescence is associated with persistent DDR. The molecular bases that distinguish transient from persistent DDR are unknown. Here we show that a large fraction of exogenously-induced persistent DDR markers are associated with telomeric DNA in cultured cells and mammalian tissues. In yeast, a chromosomal DNA double-strand break (DSB) next to telomeric sequences resists repair and impairs DNA ligase 4 recruitment. In mammalian cells, ectopic localization of telomeric factor TRF2 next to a DSB induces persistent DNA damage and DDR. Linear telomeric DNA, but not circular or scrambled DNA, induces a prolonged checkpoint in normal cells. In terminally-differentiated tissues of old primates, DDR markers accumulate at telomeres which are not critically short. We propose that linear genomes are not uniformly reparable and telomeric DNA tracts, if damaged, are irreparable and trigger persistent DDR and cellular senescence.
Cellular senescence, a stress induced growth arrest of somatic cells, was first documented in cell cultures over forty years ago, however its physiological significance has only recently been demonstrated. Using novel biomarkers of cellular senescence we examined whether senescent cells accumulate in tissues from baboons of ages encompassing the entire lifespan of this species. We show that dermal fibroblasts, displaying markers of senescence such as telomere damage, active checkpoint kinase ATM, high levels of heterochromatin proteins and elevated levels of p16, accumulate in skin biopsies from baboons with advancing age. The number of dermal fibroblasts containing damaged telomeres reaches a value of over 15% of total fibroblasts, whereas 80% of cells contain high levels of the heterochromatin protein HIRA. In skeletal muscle, a postmitotic tissue, only a small percentage of myonuclei containing damaged telomeres were detected regardless of animal age. The presence of senescent cells in mitotic tissues might therefore be a contributing factor to aging and age related pathology and provides further evidence that cellular senescence is a physiological event.
Telomeres are engaged in a host of cellular functions, and their length is regulated by multiple genes. Telomere shortening, in the course of somatic cell replication, ultimately leads to replicative senescence. In humans, rare mutations in genes that regulate telomere length have been identified in monogenic diseases such as dyskeratosis congenita and idiopathic pulmonary fibrosis, which are associated with shortened leukocyte telomere length (LTL) and increased risk for aplastic anemia. Shortened LTL is observed in a host of aging-related complex genetic diseases and is associated with diminished survival in the elderly. We report results of a genome-wide association study of LTL in a consortium of four observational studies (n = 3,417 participants with LTL and genome-wide genotyping). SNPs in the regions of the oligonucleotide/ oligosaccharide-binding folds containing one gene (OBFC1; rs4387287; P = 3.9 × 10 −9) and chemokine (C-X-C motif) receptor 4 gene (CXCR4; rs4452212; P = 2.9 × 10 −8) were associated with LTL at a genome-wide significance level (P < 5 × 10 −8). We attempted replication of the top SNPs at these loci through de novo genotyping of 1,893 additional individuals and in silico lookup in another observational study (n = 2,876), and we confirmed the association findings for OBFC1 but not CXCR4. In addition, we confirmed the telomerase RNA component (TERC) as a gene associated with LTL (P = 1.1 × 10 −5). The identification of OBFC1 through genome-wide association as a locus for interindividual variation in LTL in the general population advances the understanding of telomere biology in humans and may provide insights into agingrelated disorders linked to altered LTL dynamics.eukocyte telomere length (LTL) undergoes progressive attrition with age and is relatively short in aging-related diseases, most notably atherosclerosis (1, 2). LTL displays high interindividual variation at birth (3, 4) and thereafter (5-7), and it is longer in women than in men (8-11) and longer in African Americans than in whites of European descent (10). Although controversy existed regarding the relation of LTL to survival in the elderly, recent studies in same-sex elderly twins have found that the twin with shorter LTL was more likely to die before the twin with longer LTL (12, 13).
Oncogene-induced telomere dysfunction enforces cellular senescence in human cancer precursor lesionsThis study offers a novel view on the role of telomere attrition in human tumours, providing evidence for tumour suppressor activity resulting from telomere dysfunction-induced DNA damage responses.
Cellular senescence is a tumour suppressor mechanism that is triggered by cancer-initiating or promoting events in mammalian cells. The molecular underpinnings for this stable arrest involve transcriptional repression of proliferation-promoting genes regulated by the retinoblastoma (Rb)/E2F repressor complex. Here, we demonstrate that AGO2, Rb and microRNAs (miRs), as exemplified here by let-7, physically and functionally interact to repress Rb/E2F target genes in senescence, a process that we refer to as senescence-associated transcriptional gene silencing (SA-TGS). Herein, AGO2 acts as the effector protein for miR-let7-directed implementation of silent state chromatin modifications at target promoters and inhibition of the let-7-AGO2 effector complex perturbs the timely execution of senescence. Thus, we identify cellular senescence as the an endogenous signal of miR-AGO2-mediated TGS in human cells. Our results suggest that miR-AGO2-mediated SA-TGS may contribute to tumour suppression by stably repressing proliferation-promoting genes in pre-malignant cancer cells.
Short leukocyte telomere length (LTL) is associated with atherosclerosis in adults and diminished survival in the elderly. LTL dynamics are defined by LTL at birth, which is highly variable, and its age-dependent attrition thereafter, which is rapid during the first 20 years of life. We examined whether age-dependent LTL attrition during adulthood can substantially affect individuals’ LTL ranking (e.g., longer or shorter LTL) in relation to their peers. We measured LTL in samples donated 12 years apart on average by 1156 participants in four longitudinal studies. We observed correlations of 0.91–0.96 between baseline and follow-up LTLs. Ranking individuals by deciles revealed that 94.1% (95% confidence interval of 92.6–95.4%) showed no rank change or a 1 decile change over time. We conclude that in adults, LTL is virtually anchored to a given rank with the passage of time. Accordingly, the links of LTL with atherosclerosis and longevity appear to be established early in life. It is unlikely that lifestyle and its modification during adulthood exert a major impact on LTL ranking.
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