A progressive reduction in autophagic capacity contributes to induction of replicative senescence in Hs68 cells

Autophagy has been implicated in delayed aging and extended longevity. Here, we aimed to study the possible effects of autophagy during the progression of replicative senescence, which is one of the major features of aging. Human foreskin fibroblasts, Hs68 cells, at an initial passage of 15 were serially cultured for several months until they reached cellular senescence. A decrease in cell proliferation was observed during the progression of senescence. Induction of replicative senescence in aged cells (at passage 40) was confirmed by senescence-associated β-galactosidase (SA-β-gal) activity that represents a sensitive and reliable marker for quantifying senescent cells. We detected a significantly increased percentage (%) of SA-β-gal-positive cells at passage 40 (63%) when compared with the younger SA-β-gal-positive cells at passage 15 (0.5%). Notably, the gradual decrease in basal autophagy coincided with replicative senescence induction. However, despite decreased basal autophagic activity in senescent cells, autophagy inducers could induce autophagy in senescent cells. RT-PCR analysis of 11 autophagy-related genes revealed that the decreased basal autophagy in senescent cells might be due to the downregulation of autophagy-regulatory proteins, but not autophagy machinery components. Moreover, the senescence phenotype was not induced in the cells in which rapamycin was added to the culture to continuously induce autophagy from passage 29 until passage 40. Together, our findings suggest that reduced basal autophagy levels due to downregulation of autophagy-regulatory proteins may be the mechanism underlying replicative senescence in Hs68 cells.     

Viral infections induce abundant numbers of senescent CD8 T cells.

Viral infections are often accompanied by extensive proliferation of reactive CD8 T cells. After a defined number of divisions, normal somatic cells enter a nonreplicative stage termed senescence. In the present study we have identified the inhibitory killer cell lectin-like receptor G1 (KLRG1) as a unique marker for replicative senescence of murine CD8 T cells. KLRG1 expression was induced in a substantial portion (30-60%) of CD8 T cells in C57BL/6 mice infected with lymphocytic choriomeningitis virus (LCMV), vesicular stomatitis virus, or vaccinia virus. Similarly, KLRG1 was found on a large fraction of LCMV gp33 peptide-specific TCR-transgenic (tg) effector and memory cells activated in vivo using an adoptive transfer model. Transfer experiments with CFSE-labeled TCR-tg cells into LCMV-infected hosts further indicated that induction of KLRG1 expression required an extensive number of cell divisions. Most importantly, KLRG1(+) TCR-tg effector/memory cells could efficiently lyse target cells and secrete cytokines, but were severely impaired in their ability to proliferate after Ag stimulation. Thus, this study demonstrates that senescent CD8 T cells are induced in abundant numbers during viral infections in vivo.     

胸苷激酶基因在人二倍体成纤维细胞衰老过程中的表达调控

为研究人胸苷激酶 (humanthymidinekinase ,hTK)基因在复制衰老细胞及早衰细胞中表达下调的分子机制 ,构建了含hTK启动子的荧光素酶报告基因载体 .转染结果显示 ,复制衰老细胞与早衰细胞中hTK启动子的转录活性比年轻细胞中下降了近 3倍 ,表明转录水平的调控是hTK在衰老细胞中表达下降的主要调控机制 .定点突变的结果显示 ,转录因子Sp1、NF Y结合位点的突变可使hTK启动子活性降低近 5 0 % ,而E2F结合位点的突变可使其活性升高 2倍多 ,提示Sp1和NF Y是hTK基因的转录活化因子 ,而E2F为转录抑制因子 .电泳迁移率变更实验发现 ,与年轻细胞相比 ,Sp1、NF Y与hTK启动子的DNA结合活性在复制衰老细胞和早衰细胞中无明显改变 ,提示转录活化因子Sp1、NF Y并非hTK在衰老细胞中下调的主要因素 .染色质免疫共沉淀结果显示 ,在细胞内Rb结合在hTK启动子上 ,且同年轻细胞相比 ,复制衰老细胞及早衰细胞中的hTK启动子结合着更多的Rb ,这提示细胞衰老过程中Rb的去磷酸化可能与hTK基因在衰老过程中的下调有关 .     

Modulation of CD28 expression: distinct regulatory pathways during activation and replicative senescence.

The costimulatory molecule CD28 has a restricted tissue distribution and is expressed on T cells and some plasmacytoma cells. Although CD28 is constitutively expressed, its expression is transiently down-regulated following T cell activation and declines progressively with in vitro senescence. In vivo, CD8+ T cells and, less frequently, CD4+ T cells may completely lose CD28 surface expression during chronic infections and with aging. This correlates with changes of nuclear protein-binding activities to two motifs, site alpha and beta, within the CD28 minimal promoter. Both alpha- and beta-bound complexes are found only in lymphoid tissues, in CD28+ T cells, and in some transformed B cells. These complexes are coordinately expressed except during replicative senescence, which is characterized by the down-modulation of site beta- but not site alpha-binding activities. In contrast, T cell activation induces a parallel decline in both site alpha- and beta-binding activities. CD4+ and CD8+ T cells differ in their beta-binding profiles, which may explain the more pronounced down-regulation of CD28 in senescent CD8+ T cells. In vivo expanded CD4+CD28null and CD8+CD28null T cells uniformly lack alpha- and beta-bound complexes, resembling the pattern seen in chronically activated cells and not of senescent cells.     

Oxidative stress-mediated early senescence contributes to the short replicative life span of human peritoneal mesothelial cells

The replicative life span of cells in culture is thought to be determined by the gradually rising pool of senescent cells rather than by the simultaneous loss of proliferative capacity by all cells in the population. We found that early-passage cultures of human peritoneal mesothelial cells (HPMCs) contained a significant fraction of senescent-like cells. Furthermore, early-passage populations with a high percentage of senescent cells had a reduced subsequent life span in culture compared with populations consisting of the same number of apparently young cells but containing no senescent cells. The exposure of early-passage HPMCs to the conditioned medium from cultures containing senescent cells resulted in the retardation of growth and the induction of senescence-associated beta-galactosidase (SA-beta-Gal). This effect could be partly reduced by neutralizing TGF-beta1 activity. The timely treatment with N-tert-butyl-alpha-phenylnitrone (PBN) reduced oxidative stress, the number of early senescent cells, TGF-beta1 secretion, and ultimately extended the population life span. The effect was evident only when PBN was introduced at a very early, but not at a late, phase of tissue culture history. These results indicate that a sudden onset of senescence in early-passage HPMCs is related to oxidative stress and may influence the replicative life span of the population as a whole.     

Genetic manipulation of telomerase in HIV-specific CD8+ T cells: enhanced antiviral functions accompany the increased proliferative potential and telomere length stabilization

A large proportion of the CD8(+) T cell pool in persons chronically infected with HIV consists of cells that show features of replicative senescence, an end stage characterized by irreversible cell cycle arrest, multiple genetic and functional changes, and shortened telomeres. The objective of our research was to determine whether constitutive expression of the gene for the human telomerase (hTERT) can prevent senescence-induced impairments in human virus-specific CD8(+) T cells, particularly in the context of HIV-1 disease. Our results indicate that hTERT-expressing HIV-specific CD8(+) lymphocytes show both an enhanced and sustained capacity to inhibit HIV-1 replication in in vitro coculture experiments, as well as prolonged ability to produce IFN-gamma and TNF-alpha in response to stimulation with HIV-1-derived peptides, as compared with vector-transduced controls. Loss of CD28 expression, the signature change of replicative senescence in cell culture, was retarded in those CD8(+) T cell cultures that had high levels of CD28 at the time of hTERT transduction. These findings suggest that telomere shortening may be the primary driving force behind several aspects of CD8(+) T cell dysfunction associated with replicative senescence. We also demonstrate reduced accumulation of the p16(INK4a) and p21(WAF1) cell cycle inhibitors in hTERT-transduced lymphocytes, providing a possible mechanism by which stable hTERT expression is able to circumvent the senescence barrier in CD8(+) T cells. Given the key role of CD8(+) T cell function in controlling a variety of acute and latent viral infections, approaches to retard the functional decrements associated with replicative senescence may lead to novel types of immunotherapy.     

Importance of serum source for the in vitro replicative senescence of human bone marrow derived mesenchymal stem cells

Human mesenchymal stem cells (hMSCs) may be used for therapeutic applications. Culture conditions such as the serum source may impact on cell quality and the onset of replicative senescence. We have examined the effect of culturing hMSCs in autologous serum (AS) versus fetal bovine serum (FBS) on factors involved in in vitro replicative senescence. hMSCs from four donors were cultured in 10% FBS or 10% AS until they reached senescence. Cells were harvested at early passage and near senescence to study factors known to be involved in cellular senescence. The number of population doublings till senescence was similar for cells cultured in FBS, but varied greatly for hMSCs cultured in AS. FBS cells accumulated in S phase of cell cycle. This could not be explained by increased expression of cell cycle inhibitor proteins. Heat shock proteins were upregulated in AS compared to FBS cells. Reactive oxygen species and nitric oxide were upregulated in senescent FBS cells. Telomeres were shorter in senescent cells, more significantly in FBS cells. The source of serum was a determinant for the time till senescence in cultured hMSC. Serum source affected aspects of cell cycle regulation and the levels of heat shock proteins. Several mechanisms are likely to be responsible for replicative senescence in hMSC. Insight into the molecular details of how serum factors impacts on these mechanisms is important for the safe use of hMSCs in clinical applications.     

Recent advances in cellular senescence, cancer and aging

How much do we know about the biology of aging from cell culture studies? Most normal somatic cells have a finite potential to divide due to a process termed cellular or replicative senescence. A growing body of evidence suggests that senescence evolved to protect higher eukaryotes, particularly mammals, from developing cancer. We now know that telomere shortening, due to the biochemistry of DNA replication, induces replicative senescence in human cells. However, in rodent cells, replicative senescence occurs despite very long telomeres. Recent findings suggest that replicative senescence is just the tip of the iceberg of a more general process termed cellular senescence. It appears that cellular senescence is a response to potentially oncogenic insults, including oxidative damage. In young organisms, growth arrest by cell senescence suppresses tumor development, but later in life, due to the accumulation of senescent cells which secret factors that can disrupt tissues during aging, cellular senescence promotes tumorigenesis. Therefore, antagonistic pleiotropy may explain in part, if not in whole, the apparently paradoxical effects of cellular senescence, though this still remains an open question.     

T-cell senescence: a culprit of immune abnormalities in chronic inflammation and persistent infection

Long-lived clonal T cells deficient in CD28 expression are commonly found in patients with inflammatory syndromes and persistent infections. Considering that CD28 loss is the most consistent immunological marker of aging, we propose that, in pathological states, CD28(null) T cells represent prematurely senescent cells resulting from persistent immune activation. These unusual lymphocytes have aberrant functions that contribute to disease-related immune abnormalities, and the degree of accumulation of CD28(null) T cells predicts the severity of clinical manifestations. We suggest that understanding of the biological properties of T cells that have reached replicative senescence will influence the future management of certain diseases. Indeed, studies on the molecular basis for the loss of CD28 are already providing information on methods to functionally rescue senescent T cells.     

Extension of replicative lifespan in WI-38 human fibroblasts by dexamethasone treatment is accompanied by suppression of p21 Waf1/Cip1/Sdi1 levels

Numerous studies have shown that supplementation of the growth medium of human fibroblasts with dexamethasone at physiologic concentrations extends replicative lifespan up to 30%. While this extension of lifespan has been used to probe various aspects of the senescent phenotype, no mechanism for the increased lifespan of human fibroblasts grown in the presence of dexamethasone has ever been identified. In the present study we present evidence that the extended lifespan of human lung fibroblasts (WI-38 cells) that occurs when these cells are maintained in culture medium supplemented with dexamethasone is accompanied by a suppression of p21(Waf1/Cip1/Sdi1) levels, which normally increase as these cells enter senescence, while p16(INK4a) levels are unaffected. These results suggest that the delay of senescence in cultures grown in the presence of dexamethasone is due to a suppression of the senescence related increase in p21(Waf1/Cip1/Sdi1). These results are consistent with models of replicative senescence in which p53 and p21(Waf1/Cip1/Sdi1) play a role in the establishment of the senescent arrest.     

Human CD8+ EMRA T cells display a senescence‐associated secretory phenotype regulated by p38 MAPK

Cellular senescence is accompanied by a senescence‐associated secretory phenotype (SASP). We show here that primary human senescent CD8⁺ T cells also display a SASP comprising chemokines, cytokines and extracellular matrix remodelling proteases that are unique to this subset and contribute to age‐associated inflammation. We found the CD8⁺ CD45RA⁺CD27^? EMRA subset to be the most heterogeneous, with a population aligning with the naïve T cells and another with a closer association to the effector memory subset. However, despite the differing processes that give rise to these senescent CD8⁺ T cells once generated, they both adopt a unique secretory profile with no commonality to any other subset, aligning more closely with senescence than quiescence. Furthermore, we also show that the SASP observed in senescent CD8⁺ T cells is governed by p38 MAPK signalling.     

Differentiation between senescence (M1) and crisis (M2) in human fibroblast cultures

Normal human fibroblasts undergo only a limited number of divisions in culture and eventually enter a nonreplicative state designated senescence or mortality stage 1 (M1). Expression of certain viral oncogenes, such as the SV40 large T antigen (SV40 T-Ag), can elicit a significant extension of replicative life span, but these cultures eventually also cease dividing. This proliferative decline has been designated crisis or mortality stage 2 (M2). BrdU incorporation assays are commonly used to distinguish between senescence (<5% labeling index) and crisis (>30% labeling index). It has not been possible, however, to ascertain whether the high labeling index, indicative of ongoing DNA replication, was caused by the presence of T-Ag. We used gene targeting to knock out both copies of the p21(CIP1/WAF1) gene in presenescent human fibroblasts. p21 -/- cells displayed an extended life span but eventually entered a nonproliferative state. In their terminally nonproliferative state both p21 +/+ and p21 -/- cultures were positive for the senescence-associated beta-galactosidase (SA-beta-gal) activity; in contrast, the labeling index of p21 +/+ cells was low (<5%) whereas the labeling index of p21 -/- cells was high (>30%). The observation that p21 -/- and SV40 T-Ag-expressing cells behave identically with respect to life span extension as well as the high labeling index in the terminally nonproliferative state indicates that crisis is not a phenomenon induced solely by viral oncogenes, but a physiological state resulting from the bypass of normal senescence mechanisms. The widely used biomarker for senescence, SA-beta-gal, cannot distinguish between senescence and crisis. We propose that all SA-beta-gal-positive cultures should be further examined for their BrdU labeling index.     

Primary human muscle precursor cells obtained from young and old donors produce similar proliferative,differentiation and senescent profiles in culture

The myogenic behaviour of primary human muscle precursor cells (MPCs) obtained from young (aged 20–25 years) and elderly people (aged 67–82 years) was studied in culture. Cells were compared in terms of proliferation, DNA damage, time course and extent of myogenic marker expression during differentiation, fusion, size of the formed myotubes, secretion of the myogenic regulatory cytokine TGF‐β1 and sensitivity to TGF‐β1 treatment. No differences were observed between cells obtained from the young and elderly people. The cell populations were expanded in culture until replicative senescence. Cultures that maintained their initial proportion of myogenic cells (desmin positive) with passaging (n = 5) were studied and compared with cells from the same individuals in the non‐senescent state. The senescent cells exhibited a greater number of cells with DNA damage (γ‐H2AX positive), showed impaired expression of markers of differentiation, fused less well, formed smaller myotubes and secreted more TGF‐β. The data strongly suggest that MPCs from young and elderly people have similar myogenic behaviour.     

CMV seropositivity and T‐cell senescence predict increased cardiovascular mortality in octogenarians: results from the Newcastle 85+ study

Although chronic infection with cytomegalovirus (CMV) is known to drive T lymphocytes toward a senescent phenotype, it remains controversial whether and how CMV can cause coronary heart disease (CHD). To explore whether CMV seropositivity or T‐cell populations associated with immunosenescence were informative for adverse cardiovascular outcome in the very old, we prospectively analyzed peripheral blood samples from 751 octogenarians (38% males) from the Newcastle 85+ study for their power to predict survival during a 65‐month follow‐up (47.3% survival rate). CMV‐seropositive participants showed a higher prevalence of CHD (37.7% vs. 26.7%, P = 0.030) compared to CMV‐seronegative participants together with lower CD4/CD8 ratio (1.7 vs. 4.1, P < 0.0001) and higher frequencies of senescence‐like CD4 memory cells (41.1% vs. 4.5%, P < 0.001) and senescence‐like CD8 memory cells (TEMRA, 28.1% vs. 6.7%, P < 0.001). CMV seropositivity was also associated with increased six‐year cardiovascular mortality (HR 1.75 [1.09–2.82], P = 0.021) or death from myocardial infarction and stroke (HR 1.89 [107–3.36], P = 0.029). Gender‐adjusted multivariate Cox regression analysis revealed that low percentages of senescence‐like CD4 T cells (HR 0.48 [0.32–0.72], P < 0.001) and near‐senescent (CD27 negative) CD8 T cells (HR 0.60 [0.41–0.88], P = 0.029) reduced the risk of cardiovascular death. For senescence‐like CD4, but not near‐senescent CD8 T cells, these associations remained robust after additional adjustment for CMV status, comorbidities, and inflammation markers. We conclude that CMV seropositivity is linked to a higher incidence of CHD in octogenarians and that senescence in both the CD4 and CD8 T‐cell compartments is a predictor of overall cardiovascular mortality as well as death from myocardial infarction and stroke.     

Predicting cytotoxic T-cell age from multivariate analysis of static and dynamic biomarkers

Adoptive T-cell transfer therapy relies upon in vitro expansion of autologous cytotoxic T cells that are capable of tumor recognition. The success of this cell-based therapy depends on the specificity and responsiveness of the T cell clones before transfer. During ex vivo expansion, CD8+ T cells present signs of replicative senescence and loss of function. The transfer of nonresponsive senescent T cells is a major bottleneck for the success of adoptive T-cell transfer therapy. Quantitative methods for assessing cellular age and responsiveness will facilitate the development of appropriate cell expansion and selection protocols. Although several biomarkers of lymphocyte senescence have been identified, these proteins in isolation are not sufficient to determine the age-dependent responsiveness of T cells. We have developed a multivariate model capable of extracting combinations of markers that are the most informative to predict cellular age. To acquire signaling information with high temporal resolution, we designed a microfluidic chip enabling parallel lysis and fixation of stimulated cell samples on-chip. The acquisition of 25 static biomarkers and 48 dynamic signaling measurements at different days in culture, integrating single-cell and population based information, allowed the multivariate regression model to accurately predict CD8+ T-cell age. From surface marker expression and early phosphorylation events following T-cell receptor stimulation, the model successfully predicts days in culture and number of population doublings with R2=0.91 and 0.98, respectively. Furthermore, we found that impairment of early signaling events following T cell receptor stimulation because of long term culture allows prediction of costimulatory molecules CD28 and CD27 expression levels and the number of population divisions in culture from a limited subset of signaling proteins. The multivariate analysis highlights the information content of both averaged biomarker values and heterogeneity metrics for prediction of cellular age within a T cell population.     

Regulation of apoptosis and replicative senescence in CD8+ T cell following acute viral infection

Viral infections are characterised by a large expansion of CD8⁺ effector T cells. Once generated, these T cells must be cleared and homeostasis re-established. In this review we describe two mechanisms, apoptosis and replicative senescence which are thought to play a vital role in this process. Apoptosis clears the unwanted T cells at the end of an immune response whereas replicative senescence prevents unlimited expansion of T cells. For successful memory to be produced T cells must avoid apoptosis and avoid replicative senescence.