Physiological deterioration associated with breeding in female mice: a model for the study of senescence and aging

Longevity is a complex and dynamic process influenced by a diversity of factors. Amongst other, gestation and lactation contribute to organismal decline because they represent a great energetic investment in mammals. Here we compared the rate of senescence onset observed in primary fibroblast obtained from the lungs of retired female breeder mice (12 months old), with the senescence arrival observed in fibroblasts derived from age-matched nulliparous mice. Two-month-old animals were also used as controls of young, fully-developed adults. Cell proliferation, DNA synthesis, and expression of senescence-associated beta-galactosidase activity were evaluated as senescent parameters. In order to test differences in energetic competence at a systemic level, mitochondrial respiration was also evaluated in mitochondria isolated from the livers of the same animals used for the primary cultures. Our data indicated that the cells derived from female mice subjected to the physiological stress of breeding onset into replicative senescence prior than the cells from female mice age-matched without that particular stress. Thus validating the use of retired breeders as a model to study aging and senescence at the cellular level.     

Novel monoclonal antibodies identify antigenic determinants unique to cellular senescence.

Normal human diploid fibroblasts exhibit a limited lifespan in vitro and are used as a model to study in vivo aging. Monoclonal antibodies were generated against partially purified surface membranes from human diploid fibroblasts at the end of their lifespan (senescent). Three hybridomas were isolated that secreted antibodies reacting to cellular determinants expressed specifically on senescent human fibroblasts of different origin, including neonatal foreskin, embryonic lung, and adult skin punch biopsy, but not expressed on matched young cells. The antibodies did not bind to immortal human cells and normal young cells made reversibly nondividing, indicating the antigens are not expressed in cells that are not senescent. The antibodies identified senescent cells in a mixed cell population and expression of the senescent cell antigens correlated strongly with the cells inability to synthesize DNA at the onset of senescence. The antigens appeared to be cell surface or extracellular matrix associated, and the epitopes were destroyed by mild trypsin treatment. Western analysis indicated all three antibodies reacted with fibronectin. Though the antigenic determinants on the fibronectin molecule were not accessible in the intact young cell, the epitopes were present in fibronectin extracted from both senescent and young cells, as well as purified human plasma fibronectin. These antibodies and the senescent specific expression of the antigens provide powerful tools to investigate the mechanisms leading to in vitro senescence. This may enable us to investigate directly the relationship between cellular aging and aging of the individual.     

The bystander effect contributes to the accumulation of senescent cells in vivo

Senescent cells accumulate with age in multiple tissues and may cause age‐associated disease and functional decline. In vitro, senescent cells induce senescence in bystander cells. To see how important this bystander effect may be for accumulation of senescent cells in vivo, we xenotransplanted senescent cells into skeletal muscle and skin of immunocompromised NSG mice. 3 weeks after the last transplantation, mouse dermal fibroblasts and myofibres displayed multiple senescence markers in the vicinity of transplanted senescent cells, but not where non‐senescent or no cells were injected. Adjacent to injected senescent cells, the magnitude of the bystander effect was similar to the increase in senescence markers in myofibres between 8 and 32 months of age. The age‐associated increase of senescence markers in muscle correlated with fibre thinning, a widely used marker of muscle aging and sarcopenia. Senescent cell transplantation resulted in borderline induction of centrally nucleated fibres and no significant thinning, suggesting that myofibre aging might be a delayed consequence of senescence‐like signalling. To assess the relative importance of the bystander effect versus cell‐autonomous senescence, we compared senescent hepatocyte frequencies in livers of wild‐type and NSG mice under ad libitum and dietary restricted feeding. This enabled us to approximate cell‐autonomous and bystander‐driven senescent cell accumulation as well as the impact of immunosurveillance separately. The results suggest a significant impact of the bystander effect for accumulation of senescent hepatocytes in liver and indicate that senostatic interventions like dietary restriction may act as senolytics in immunocompetent animals.     

Complex mechanisms underlying impaired activation of Cdk4 and Cdk2 in replicative senescence: roles of p16, p21, and cyclin D1

Numerous changes in gene expression are known to occur during replicative senescence, including changes in genes involved in the cell cycle control. In the present study, we have found a severe impairment in the activation of Cdk2 and Cdk4 in response to mitogens in senescent human fibroblasts and determined the molecular basis for this. Although Cdk4 protein was constitutively expressed in senescent cells at the same level as in early-passage young cells, it was found to be complexed with a distinct set of Cdk inhibitors. Cdk4 derived from early passage quiescent cells was effectively activated by incubation with cyclin D1 and Cdk-activating kinase (CAK) in vitro, whereas Cdk4 from senescent cells was not. Cdk2 protein was dramatically decreased in senescent cells and complexed primarily with cyclin D1 and p21. This cyclin D1-bound Cdk2 was not activated by CAK either in vivo or in vitro, implicating cyclin D1 as an inhibitor of Cdk2 activation. Thus, one of the underlying molecular events involved in replicative senescence is the impaired activation of Cdk4 and Cdk2 due to increased binding of p16 to Cdk4 and increased association of Cdk2 with cyclin D1 and p21.     

Effect of clonal senescence on low density lipoprotein-receptor activity of bovine arterial endothelial cells

Senescent and young bovine arterial endothelial cells derived from the same parental cell clone were compared to test the effect of in vitro endothelial cell senescence on low density lipoprotein (LDL) and modified LDL-receptor activities. Low density lipoprotein binding and degradation were both increased in cells that underwent a larger number of population doublings, whereas acetyl LDL binding and degradation were unchanged. The increased LDL-receptor activity associated with endothelial cell senescence remained significant after variation of cell number among senescent and young clones was taken into account. Thus, aging endothelial cells seem capable of continuing to process LDL and modified LDL, which could play a role in the arterial wall changes that occur with age in vivo.     

Uncoupling the senescent phenotype from telomere shortening in hydrogen peroxide-treated fibroblasts

Normal human cells have a limited replicative potential and inevitably reach replicative senescence in culture. Replicatively senescent cells show multiple molecular changes, some of which are related to the irreversible growth arrest in culture, whereas others resemble the changes occurring during the process of aging in vivo. Telomeres shorten as a result of cell replication and are thought to serve as a replicometer for senescence. Recent studies show that young cells can be induced to develop features of senescence prematurely by damaging agents, chromatin remodeling, and overexpression of ras or the E2F1 gene. Accelerated telomere shortening is thought to be a mechanism of premature senescence in some models. In this work, we test whether the acquisition of a senescent phenotype after mild-dose hydrogen peroxide (H(2)O(2)) exposure requires telomere shortening. Treating young HDFs with 150 microM H(2)O(2) once or 75 microM H(2)O(2) twice in 2 weeks causes long-term growth arrest, an enlarged morphology, activation of senescence-associated beta-galactosidase, and elevated expression of collagenase and clusterin mRNAs. No significant telomere shortening was observed with H(2)O(2) at doses ranging from 50 to 200 microM. Weekly treatment with 75 microM H(2)O(2) also failed to induce significant telomere shortening. Failure of telomere shortening correlated with an inability to elevate p16 protein or mRNA in H(2)O(2)-treated cells. In contrast, p21 mRNA was elevated over 40-fold and remained at this level for at least 2 weeks after a pulse treatment of H(2)O(2). The role of cell cycle checkpoints centered on p21 in premature senescence induced by H(2)O(2) is discussed here.     

Cell replication and aging: in vitro and in vivo studies.

The relationship between human aging and cell replication has been investigated using two complementary approaches: in vitro studies of human fibroblasts derived from young and old volunteer members of the Baltimore Longitudinal Study and in vivo examinations of bone marrow cell populations from young and old mice and rats. Total proliferative capacity measured as either the onset of cell culture senescence or as in vitro life span was significantly diminished in cell cultures derived from old human donors when compared to parallel cultures established from young donors. Acute replicative abilities as measured by percent replicating cells, cell pupulation doubling time, cell number at confluency, and colony size distribution were also significantly decreased in human old cell populations. An in vivo cytogenetic technique for measuring cell replication was developed utilizing the differential staining properties of metaphase chromosomes of cells that have replicated in the presence of bromodeoxyuridine. With this technique, cell cycle times have been derived in vivo as well as in vitro. Preliminary in vivo results in both mice and rats indicate that cell replication is slowed in old animal cell populations. Further research will be directed both in vitro and in vivo at discerning the mechanisms for this impairment of cellular replication with aging.     

Aged‐senescent cells contribute to impaired heart regeneration

Aging leads to increased cellular senescence and is associated with decreased potency of tissue‐specific stem/progenitor cells. Here, we have done an extensive analysis of cardiac progenitor cells (CPCs) isolated from human subjects with cardiovascular disease, aged 32–86 years. In aged subjects (>70 years old), over half of CPCs are senescent (p16^INK4A, SA‐β‐gal, DNA damage γH2AX, telomere length, senescence‐associated secretory phenotype [SASP]), unable to replicate, differentiate, regenerate or restore cardiac function following transplantation into the infarcted heart. SASP factors secreted by senescent CPCs renders otherwise healthy CPCs to senescence. Elimination of senescent CPCs using senolytics abrogates the SASP and its debilitative effect in vitro. Global elimination of senescent cells in aged mice (INK‐ATTAC or wild‐type mice treated with D + Q senolytics) in vivo activates resident CPCs and increased the number of small Ki67‐, EdU‐positive cardiomyocytes. Therapeutic approaches that eliminate senescent cells may alleviate cardiac deterioration with aging and restore the regenerative capacity of the heart.     

Increased polyploidy in aortic vascular smooth muscle cells during aging is marked by cellular senescence

We previously reported that the frequency of polyploid aortic vascular smooth muscle cells (VSMC) serves as a biomarker of aging. Cellular senescence of somatic cells is another marker of aging that is characterized by the inability to undergo cell division. Here, we examined whether polyploidy is associated with the development of cellular senescence in vivo. Analysis of aortic tissue preparations from young and old Brown Norway rats showed that expression of senescence markers such as p16(INK4a) and senescence-associated beta-galactosidase activity are detected primarily in the old tissues. VSMC from p16(INK4a) knockout and control mice display similar levels of polyploid cells. Intriguingly, senescence markers are expressed in most, but not all, polyploid VSMC. Moreover, the polyploid cells exhibit limited proliferative capacity in comparison to their diploid counterparts. This study is the first to demonstrate in vivo that polyploid VSMC adopt a senescent phenotype.     

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.     

Replicative senescence of human skin fibroblasts correlates with a loss of regulation and overexpression of collagenase activity

The atrophy of extracellular matrix is a common event during the aging of connective tissues. In this study, we tested the hypothesis that the altered ability of senescent cells to be modulated by serum growth factors correlated with a loss of regulation of collagenase synthesis. We examined the levels of immunoreactive procollagenase and collagenase inhibitor (the tissue inhibitor of metalloproteinases, TIMP) associated with young and senescent fibroblasts cultured in vitro. Young fibroblasts cultured in low (0.5%) concentrations of fetal bovine serum respond to increased (10%) serum by increasing levels of procollagenase and TIMP beginning 4.0 h after serum stimulation. In contrast, senescent fibroblasts constitutively produce relatively high levels of procollagenase even when cultured in low levels of serum and do not respond to serum stimulation by increasing procollagenase synthesis. In addition, senescent fibroblasts constitutively express a relatively small amount of TIMP which is not induced upon serum stimulation. This altered expression of collagenase and TIMP appears unique to the senescent phenotype and not merely a result of growth inhibition, since young cells growth arrested by density-dependent growth inhibition displayed a temporal pattern of procollagenase and TIMP expression upon serum stimulation similar to that of subconfluent young cultures. An assay of net collagenase activity revealed a greater than 20-fold elevation of activity in trypsin-activated extracts from senescent versus young fibroblasts when cultured in a low concentration of fetal bovine serum. These results demonstrate for the first time a direct correlation between alterations in the molecular pathways regulating connective tissue homeostasis and those of replicative senescence. The increased collagenolytic activity of senescent compared to young fibroblasts cultured in the presence of a low serum concentration suggests that aging fibroblasts may become increasingly fibroclastic causing many of the age-associated alterations in dermal collagen observed during aging in vivo.     

Senescent cells at the crossroads of aging,disease, and tissue homeostasis

Originally identified as an outcome of continuous culture of primary cells, cellular senescence has moved beyond the culture dish and is now a bona fide driver of aging and disease in animal models, and growing links to human disease. This cellular stress response consists of a stable proliferative arrest coupled to multiple phenotypic changes. Perhaps the most important of these is the senescence-associated secretory phenotype, or senescence-associated secretory phenotype —a complex and variable collection of secreted molecules release by senescent cells with a number of potent biological activities. Senescent cells appear in multiple age-associated conditions in humans and mice, and interventions that eliminate these cells can prevent or even reverse multiple diseases in mouse models. Here, we review salient aspects of senescent cells in the context of human disease and homeostasis. Senescent cells increase in abundance during several diseases that associated with premature aging. Conversely, senescent cells have a key role in beneficial processes such as development and wound healing, and thus can help maintain tissue homeostasis. Finally, we speculate on mechanisms by which deleterious aspects of senescent cells might be targeted while retaining homeostatic aspects in order to improve age-related outcomes.     

DNA methylation pattern changes upon long-term culture and aging of human mesenchymal stromal cells

Within 2–3 months of in vitro culture-expansion, mesenchymal stromal cells (MSC) undergo replicative senescence characterized by cell enlargement, loss of differentiation potential and ultimate growth arrest. In this study, we have analyzed DNA methylation changes upon long-term culture of MSC by using the HumanMethylation27 BeadChip microarray assessing 27 578 unique CpG sites. Furthermore, we have compared MSC from young and elderly donors. Overall, methylation patterns were maintained throughout both long-term culture and aging but highly significant differences were observed at specific CpG sites. Many of these differences were observed in homeobox genes and genes involved in cell differentiation. Methylation changes were verified by pyrosequencing after bisulfite conversion and compared to gene expression data. Notably, methylation changes in MSC were overlapping in long-term culture and aging in vivo . This supports the notion that replicative senescence and aging represent developmental processes that are regulated by specific epigenetic modifications.     

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.     

Differential roles for cyclin-dependent kinase inhibitors p21 and p16 in the mechanisms of senescence and differentiation in human fibroblasts

The irreversible G1 arrest in senescent human diploid fibroblasts is probably caused by inactivation of the G1 cyclin-cyclin-dependent kinase (Cdk) complexes responsible for phosphorylation of the retinoblastoma protein (pRb). We show that the Cdk inhibitor p21(Sdi1,Cip1,Waf1), which accumulates progressively in aging cells, binds to and inactivates all cyclin E-Cdk2 complexes in senescent cells, whereas in young cells only p21-free Cdk2 complexes are active. Furthermore, the senescent-cell-cycle arrest occurs prior to the accumulation of the Cdk4-Cdk6 inhibitor p16(Ink4a), suggesting that p21 may be sufficient for this event. Accordingly, cyclin D1-associated phosphorylation of pRb at Ser-780 is lacking even in newly senescent fibroblasts that have a low amount of p16. Instead, the cyclin D1-Cdk4 and cyclin D1-Cdk6 complexes in these cells are associated with an increased amount of p21, suggesting that p21 may be responsible for inactivation of both cyclin E- and cyclin D1-associated kinase activity at the early stage of senescence. Moreover, even in the late stage of senescence when p16 is high, cyclin D1-Cdk4 complexes are persistent, albeit reduced by 相似文献   

Is beta-galactosidase staining a marker of senescence in vitro and in vivo?

Cytochemically detectable beta-galactosidase (beta-gal) at pH 6.0 has been reported to increase during the replicative senescence of fibroblast cultures and has been used widely as a marker of cellular senescence in vivo and in vitro. In this study, we have characterized changes in senescence-associated (SA) beta-gal staining in early and late passage cultures, cultures established from donors of different ages, virally immortalized cells, and tissue slices obtained from donors of different ages. The effects of different culture conditions were also examined. While we confirm the previous report that SA beta-gal staining increased in low-density cultures of proliferatively senescent cells, we were unable to demonstrate that it is a specific marker for aging in vitro. Cultures established from donors of different ages stained for SA beta-gal activity as a function of in vitro replicative age, not donor age. We also failed to observe any differences in SA beta-gal staining in skin cells in situ as a marker of aging in vivo. The level of cytochemically detectable SA beta-gal was elevated in confluent nontransformed fibroblast cultures, in immortal fibroblast cultures that had reached a high cell density, and in low-density, young, normal cultures oxidatively challenged by treatment with H2O2. Although we clearly demonstrate that SA beta-gal staining in cells is increased under a variety of different conditions, the interpretation of increased staining remains unclear, as does the question of whether the same mechanisms are responsible for the increased SA beta-gal staining observed in senescent cells and changes observed in cells under other conditions.     

Effect of clonal senescence on low density lipoprotein-receptor activity of bovine arterial endothelial cells

Summary Senescent and young bovine arterial endothelial cells derived from the same parental cell clone were compared to test the effect of in vitro endothelial cell senescence on low density lipoprotein (LDL) and modified LDL-receptor activities. Low density lipoprotein binding and degradation were both increased in cells that underwent a larger number of population doublings, whereas acetyl LDL binding and degradation were unchanged. The increased LDL-receptor activity associated with endothelial cell senescence remained significant after variation of cell number among senescent and young clones was taken into account. Thus, aging endothelial cells seem capable of continuing to process LDL and modified LDL, which could play a role in the arterial wall changes that occur with age in vivo. This study was supported by National Institutes of Health Grants AG 02673 and HL 18645. Computational assistance was provided by CLINFO computer system funded under General Clinical Research Center Grant RR-37.     

Relationship of finite proliferative lifespan, senescence, and quiescence in human cells

Cell hybrids were formed between human diploid fibroblasts (HDF) and carcinogen-transformed HDF to determine the relationship among: (1) finite proliferative lifespan, which we define as an age-related failure of a population to achieve one population doubling in 4 weeks; (2) arrest in a senescent state, which we define as cessation of DNA synthesis in a viable culture that is at the end of its lifespan by the above definition; and (3) arrest in a quiescent state, which we define as cessation of DNA synthesis in a young culture that is crowded or mitogen-deprived. HDF express all three of these phenotypes, which we have abbreviated FPL+, S+, and Q+, respectively. Carcinogen-transformed HDF are transformed to immortality (FPL-) and inability to achieve quiescence (Q-). They have no S phenotype because, by definition, this phenotype only exists in FPL+ cells. Fusion of FPL+, Q+, S+ HDF X FPL-, Q- carcinogen-transformed HDF produced hybrid clones that were FPL+, Q-, and S-, where the S- phenotype means that individual cells continued to synthesize DNA in cultures that had reached the end of their lifespan by our definition. These results are consistent with our hypothesis that senescent HDF and quiescent HDF may share a common mechanism for arrest in G1 phase. We have suggested that this could occur if the aging mechanism that is responsible for the FPL+ phenotype is a progressive decrease in the ability of cells to recognize or respond to mitogenic growth factors. If so, then cells would become physiologically mitogen-deprived at the end of their lifespan, which would cause them to arrest in the senescent state by the same mechanism that causes young cells to arrest in the quiescent state when they are mitogen-deprived. This hypothesis predicts that the FPL+ phenotype can be separated from the S+ phenotype--i.e., FPL+ cells can be S+ or S- --and that the Q and S phenotypes are linked--i.e., FPL+ cells are either Q+ and S+ or Q- and S-. Both these predictions are supported by the present data.