Telomeric 3'-overhang length is associated with the size of telomeres

Telomeres are specialized DNA/protein complexes that cap eukaryotic chromosome ends as T-loop structures and maintain genomic integrity. Vertebrate telomeric DNA consists of tandem double-strand repeats which terminate in a 3' single-strand G-rich overhang. The telomeric 3'-overhang is important for the formation of the T-loop. In mammalian mortal somatic cells, telomeres shorten with each successive division and contribute to the onset of replicative senescence. The exact molecular mechanism underlying replicative senescence remains unclear: whether telomere shortening is the only trigger or loss of telomeric 3'-overhang plays a causal role. To further address this issue, we investigated telomeric 3'-overhang and telomere changes during cell proliferation toward replicative senescence. We demonstrate here that telomeric 3'-overhang, similar to telomeres, exhibits progressive attrition with each cell division in primary sheep fibroblasts and that telomeric 3'-overhang size does not determine the rate of telomere shortening. Furthermore, the sizes of telomeric 3'-overhangs are associated with telomere lengths. Our results suggest that alteration of the 3'-overhang and the telomere during cellular proliferation are associated. Together they may contribute to maintain chromosomal stability and to regulate replicative senescence.     

Telomerase positive human diploid fibroblasts are resistant to replicative senescence but not premature senescence induced by chemical reagents

Human diploid fibroblasts in tissue culture undergo replicative senescence after a finite number of divisions that is characterized by a permanent loss of their dividing potential. However, senescence-like phenotypes, including growth cessation, morphological changes, and appearance of senescence-associated β-galactosidae (SA-gal) activity, can be induced by treating early passage cells with C₆-ceramide, H₂O₂, LY294002, or trichostatin A. While there is convincing evidence that telomere shortening is causally related to replicative senescence, the role of telomere shortening in the chemical-induced premature senescence is unclear. Here we employed a normal human BJ cell strain and its telomerase-transfected counterpart, termed BJ-T cells, to examine whether active telomerase in BJ-T can block or delay the premature senescence induced by various chemicals and, if not, whether telomere shortening still occurs. We found that, although all four chemicals tested could induce growth arrest, and in some cases SA-gal activity, in both BJ and BJ-T cells, only H₂O₂ clearly caused an irreversible loss of dividing potential. H₂O₂ treatment did not inhibit the cellular telomerase activity, nor did it cause any appreciable telomere shortening in BJ-T cells. These results suggest that oxidative stress and other chemical reagents can target at sites unrelated to the telomere-associated clocking mechanism. Alternatively these chemicals may bypass the telomere length maintenance machinery and target at its downstream sites. This revised version was published online in July 2006 with corrections to the Cover Date.     

Rapid telomere shortening in children

Telomere shortening may reflect the total number of divisions experienced by a somatic cell and is associated with replicative senescence. We found that the average rate of telomere shortening in peripheral blood mononuclear cells (PBMCs) obtained longitudinally from nine different infants during the first 3 years of life (270 bp per year) is more than fourfold higher than in adults and does not correlate with telomerase activity. These results show that the rate of telomere loss changes during ontogeny, suggesting the existence of periods of accelerated cell division. Because human immunodeficiency virus (HIV) preferentially infects actively dividing cells, our observation suggesting accelerated cell division in children may provide an explanation for some of the distinctive pathogenic features of the HIV disease in infants, including higher viral loads and more rapid progression to acquired immunodeficiency syndrome (AIDS).     

The concept of telomeric non-reciprocal recombination (TENOR) applied to human fibroblasts grown in serial cultures: concordance with genealogical data

Since the discovery of the limited life span of human fibroblasts some 50 years ago, many genealogical studies have been undertaken to describe growth kinetics of fibroblasts in serial cultures by their individual division behavior. It is now accepted that proliferation capacities of human fibroblasts strongly depend on their telomere lengths and integrity. Telomeres shorten with each replication round, and there is a direct correlation between cell division capacity and telomere lengths; that is, the consumption of disposable telomeric DNA repeats during cell divisions progresses until critically short telomeres determining the replicative senescence of the cells are present. Recently, we have suggested that telomeres in fibroblasts can also become elongated during DNA replication by telomeric non-reciprocal recombination (TENOR). Here we discuss genealogical data collected over the last decades as well as more recent findings on the telomere-driven replicative senescence process, and we summarize both to give an integrated picture.     

Dynamics of telomere shortening in neutrophils and T lymphocytes during ageing and the relationship to skewed X chromosome inactivation patterns

Human haemopoiesis undergoes profound changes throughout life, resulting in compromised regenerative capacity of haemopoietic stem cells. It has been suggested that telomere shortening results in senescence of haemopoietic stem cell subsets and may influence the balance between stem cell renewal and proliferation. Telomere length and telomerase activity was measured in whole blood leucocytes, neutrophils and T cells from cord blood and individuals aged from 1 year to 96 years. Rapid telomere shortening [700 base pairs (bp)] was demonstrated in the first year of life, followed by a gradual decline of 31 bp/year. T cells were shown to have longer telomeres than neutrophils (mean difference 372 bp, P = < 0.001) but demonstrated similar rates of shortening (20 +/- 0.3 bp/year vs. 22 +/- 0.3 bp/year). Telomerase was detectable in T cells but not in neutrophils, suggesting that telomerase is not the rate-limiting step for regulation of telomere length in haemopoietic cells. Stem cell utilization as measured by X chromosome inactivation patterns was found to be independent of telomere length. This supports the concept that age-dependent skewed haemopoiesis is the result of random stem cell loss or X-allelic exclusion rather than telomeric senescence. These studies provide insight into the ageing process and a reference point for evaluating replicative stress in individuals of different age groups.     

Replicative senescence in sheep fibroblasts is a p53 dependent process

Studies on telomere and telomerase biology are fundamental to the understanding of human ageing, and age-related diseases such as cancer. However, human studies are hampered by the lack of fully reflective animal model systems. Here we describe basic studies of telomere length and telomerase activity in sheep tissues and cells. Terminal restriction fragment lengths from sheep tissues ranged from 9 to 23 kb, with telomerase activity present in testis but suppressed in somatic tissues. Sheep fibroblasts had a finite lifespan in culture, after which the cells entered senescence. During in vitro growth the mean terminal restriction fragment lengths decreased in size at a rate of 210 and 350 bp per population doubling (PD). Senescent skin fibroblasts had increased levels of p53 and p21WAF1 compared to young cells. Incubation of senescent cells with siRNA duplexes specific for p53 suppressed p53 expression and allowed the cells to re-enter the cell cycle. Five PDs beyond senescence the siRNA-treated cells reached a second proliferative barrier. This study shows that telomere biology in sheep is similar to that in humans, with senescence in sheep GM03550 fibroblasts being a telomere-driven, p53-(p21WAF1)-dependent process. Therefore sheep may represent an alternative model system for studying telomere biology, replicative senescence, and by implication human ageing.     

Absence of telomere shortening and oxidative DNA damage in the young adult offspring of women with pre-gestational type 1 diabetes

Aims/hypothesis  The offspring of mothers with pre-gestational type 1 diabetes (PGDM) may be at increased risk of glucose intolerance and cardiovascular disease in childhood. The underlying causes of these observations, and whether they persist into adulthood, are unknown. The aim of the present study was to test the hypothesis that fetal chromosomal telomere oxidative DNA damage resulting from maternal PGDM programmes the offspring towards a senescent phenotype that is detectable in young adulthood. Methods  We studied 21 young adult offspring (age 16–23 years) with a maternal history of PGDM and 23 age- and weight-matched controls with no maternal history of diabetes. All participants underwent anthropometric assessments, a standard 75 g OGTT, measurement of peripheral blood mononuclear cell and skin fibroblast telomere length, fibroblast senescence, cell DNA damage (by determination of 8-oxoguanine levels using flow cytometry), plasma lipoprotein profiles (determined by nuclear magnetic resonance) and plasma levels of soluble adhesion molecules and inflammatory markers. Results  The groups did not differ significantly with respect to anthropometric measures, glucose tolerance, fasting and 2 h plasma insulin levels during OGTT, estimated peripheral insulin resistance, peripheral blood mononuclear cell or fibroblast telomere length, DNA damage or senescence in vitro, plasma NMR lipoprotein profiles or levels of high-sensitivity C-reactive protein. Plasma concentrations of soluble intercellular adhesion molecule 1 (sICAM-1; p < 0.05) and IL-6 (p = 0.08) were higher in the PGDM offspring. Conclusions/interpretation  Young adult offspring of mothers with PGDM do not differ in terms of glucose tolerance, DNA damage or telomere length from controls of the same weight and BMI. This does not preclude such abnormalities at an earlier age, but there is no evidence of telomere damage as a pre-programming mechanism in the young adults enrolled in this study.     

Cellular and molecular mechanisms of stress-induced premature senescence (SIPS) of human diploid fibroblasts and melanocytes

Replicative senescence of human diploid fibroblasts (HDFs) or melanocytes is caused by the exhaustion of their proliferative potential. Stress-induced premature senescence (SIPS) occurs after many different sublethal stresses including H(2)O(2), hyperoxia, or tert-butylhydroperoxide. Cells in replicative senescence share common features with cells in SIPS: morphology, senescence-associated beta-galactosidase activity, cell cycle regulation, gene expression and telomere shortening. Telomere shortening is attributed to the accumulation of DNA single-strand breaks induced by oxidative damage. SIPS could be a mechanism of accumulation of senescent-like cells in vivo. Melanocytes exposed to sublethal doses of UVB undergo SIPS. Melanocytes from dark- and light- skinned populations display differences in their cell cycle regulation. Delayed SIPS occurs in melanocytes from light-skinned populations since a reduced association of p16(Ink-4a) with CDK4 and reduced phosphorylation of the retinoblastoma protein are observed. The role of reactive oxygen species in melanocyte SIPS is unclear. Both replicative senescence and SIPS are dependent on two major pathways. One is triggered by DNA damage, telomere damage and/or shortening and involves the activation of the p53 and p21(waf-1) proteins. The second pathway results in the accumulation of p16(Ink-4a) with the MAP kinase signalling pathway as possible intermediate. These data corroborate the thermodynamical theory of ageing, according to which the exposure of cells to sublethal stresses of various natures can trigger SIPS, with possible modulations of this process by bioenergetics.     

Promise and problems in relating cellular senescence in vitro to aging in vivo

According to the 'Hayflick limit', human fetal fibroblasts have a uniform, limited replicative lifespan of about 50 population doublings in cell culture. This concept was extrapolated to diverse cells in the body. It seemed to decrease with the age of the cell donor and, as a form of cell senescence, was thought to underlie the aging process. More discriminating analysis, however, showed that the fibroblasts decayed in a stochastic manner from the time of their explantation, at a rate that increased with the number of population doublings in culture. There was no consistent relation to the age of the donor. Despite the contradictory evidence, the original version of the Hayflick limit retained its general acceptance. Cell senescence was attributed to the absence of telomerase in the fibroblasts, which resulted in shortening of telomeres at each division until they fell below a critical length needed for further division. However, it is well established that stem cells in renewing tissues undergo many more than 50 divisions in a lifetime, without apparent senescence. Contrary to early findings of no telomerase in most tissues, their stem cells retain telomerase and presumably telomere length despite many divisions in vivo. Massive accumulation of lipofuscin granules occurs under stress in long term crowded cultures, but the granules dissipate on subculture or neoplastic transformation. The overall results indicate a critical disjunction between cell senescence in vitro and aging in vivo. By contrast, cell culture has been useful in showing a need for telomere capping in maintaining cell stability and viability. It may also provide information about the biochemical mechanism of lipofuscin production.     

Telomere shortening and ageing

Telomeres form the ends of human chromosomes. Telomeres shorten with each round of cell division and this mechanism limits proliferation of human cells to a finite number of cell divisions by inducing replicative senescence, differentiation, or apoptosis. Telomere shortening can act as a tumor suppressor. However, as a downside, there is growing evidence indicating that telomere shortening also limits stem cell function, regeneration, and organ maintenance during ageing. Moreover, telomere shortening during ageing and disease is associated with increasing cancer risk. In this review we summarize our current knowledge on the role of telomere shortening in human ageing, chronic diseases, and cancer.