miR-223促进小鼠胚胎成纤维细胞复制性衰老

微小RNA（MicroRNAs（或miRNAs）是作为强大的基因表达调控子,广泛参与多种生命过程,在细胞衰老进程中的作用也日益受到关注。miR-223是一个典型的抑癌基因,可显著抑制细胞增殖能力。此外,miR-223与阿尔茨海默症、心血管疾病以及类风湿性关节炎等衰老相关疾病的发生发展密切相关。尽管如此,miR-223在细胞衰老进程中的作用及其分子机制尚未见报道。本研究通过连续传代建立了小鼠胚胎成纤维细胞（MEF细胞）的复制性衰老模型,并利用荧光定量qRT-PCR检测发现,miR-223在衰老MEF细胞中的表达水平显著上调。随后,通过转染miR-223模拟物Agomir-223在MEF细胞中过表达miR-223,结果显示过表达miR-223可显著促进MEF细胞的衰老表型并抑制其增殖能力,而抑制miR-223的表达可延缓MEF细胞的复制性衰老进程。进一步利用生物信息学方法预测获得多个miR-223的候选衰老相关靶基因,包括Rasa1、Ddit4和Smad1等。然而双萤光素酶报告系统结果显示,miR-223并不显著影响其萤光强度,表明它们很可能并不是miR-223的下游靶基因。综上所述,miR-223可显著促进MEF细胞复制性衰老,然而其调节细胞衰老进程的分子机制依然有待深入研究。     

Oxygen sensitivity severely limits the replicative lifespan of murine fibroblasts

Most mammalian cells do not divide indefinitely, owing to a process termed replicative senescence. In human cells, replicative senescence is caused by telomere shortening, but murine cells senesce despite having long stable telomeres. Here, we show that the phenotypes of senescent human fibroblasts and mouse embryonic fibroblasts (MEFs) differ under standard culture conditions, which include 20% oxygen. MEFs did not senesce in physiological (3%) oxygen levels, but underwent a spontaneous event that allowed indefinite proliferation in 20% oxygen. The proliferation and cytogenetic profiles of DNA repair-deficient MEFs suggested that DNA damage limits MEF proliferation in 20% oxygen. Indeed, MEFs accumulated more DNA damage in 20% oxygen than 3% oxygen, and more damage than human fibroblasts in 20% oxygen. Our results identify oxygen sensitivity as a critical difference between mouse and human cells, explaining their proliferative differences in culture, and possibly their different rates of cancer and ageing.     

Induction of replicative senescence biomarkers by sublethal oxidative stresses in normal human fibroblast

We tested the long-term effects of sublethal oxidative stresses on replicative senescence. WI-38 human diploid fibroblasts (HDFs) at early cumulative population doublings (CPDs) were exposed to five stresses with 30 microM tert-butylhydroperoxide (t-BHP). After at least 2 d of recovery, the cells developed biomarkers of replicative senescence: loss of replicative potential, increase in senescence-associated beta-galactosidase activity, overexpression of p21(Waf-1/SDI-1/Cip1), and inability to hyperphosphorylate pRb. The level of mRNAs overexpressed in senescent WI-38 or IMR-90 HDFs increased after five stresses with 30 microM t-BHP or a single stress under 450 microM H(2)O(2). These corresponding genes include fibronectin, osteonectin, alpha1(I)-procollagen, apolipoprotein J, SM22, SS9, and GTP-alpha binding protein. The common 4977 bp mitochondrial DNA deletion was detected in WI-38 HDFs at late CPDs and at early CPDs after t-BHP stresses. In conclusion, sublethal oxidative stresses lead HDFs to a state close to replicative senescence.     

Suppression of replicative senescence by rapamycin in rodent embryonic cells

The TOR (target of rapamycin) pathway is involved in aging in diverse organisms from yeast to mammals. We have previously demonstrated in human and rodent cells that mTOR converts stress-induced cell cycle arrest to irreversible senescence (geroconversion), whereas rapamycin decelerates or suppresses geroconversion during cell cycle arrest. Here, we investigated whether rapamycin can suppress replicative senescence of rodent cells. Mouse embryonic fibroblasts (MEFs) gradually acquired senescent morphology and ceased proliferation. Rapamycin decreased cellular hypertrophy, and SA-beta-Gal staining otherwise developed by 4-6 passages, but it blocked cell proliferation, masking its effects on replicative lifespan. We determined that rapamycin inhibited pS6 at 100-300 pM and inhibited proliferation with IC50 around 30 pM. At 30 pM, rapamycin partially suppressed senescence. However, the gerosuppressive effect was balanced by the cytostatic effect, making it difficult to suppress senescence without causing quiescence. We also investigated rat embryonic fibroblasts (REFs), which exhibited markers of senescence at passage 7, yet were able to slowly proliferate until 12–14 passages. REFs grew in size, acquired a large, flat cell morphology, SA-beta-Gal staining and components of DNA damage response (DDR), in particular, γH2AX/53BP1 foci. Incubation of REFs with rapamycin (from passage 7 to passage 10) allowed REFs to overcome the replicative senescence crisis. Following rapamycin treatment and removal, a fraction of proliferating REFs gradually increased and senescent phenotype disappeared completely by passage 24.     

Mitochondrial dysfunction accounts for the stochastic heterogeneity in telomere-dependent senescence

Aging is an inherently stochastic process, and its hallmark is heterogeneity between organisms, cell types, and clonal populations, even in identical environments. The replicative lifespan of primary human cells is telomere dependent; however, its heterogeneity is not understood. We show that mitochondrial superoxide production increases with replicative age in human fibroblasts despite an adaptive UCP-2–dependent mitochondrial uncoupling. This mitochondrial dysfunction is accompanied by compromised [Ca²⁺]_i homeostasis and other indicators of a retrograde response in senescent cells. Replicative senescence of human fibroblasts is delayed by mild mitochondrial uncoupling. Uncoupling reduces mitochondrial superoxide generation, slows down telomere shortening, and delays formation of telomeric γ-H2A.X foci. This indicates mitochondrial production of reactive oxygen species (ROS) as one of the causes of replicative senescence. By sorting early senescent (SES) cells from young proliferating fibroblast cultures, we show that SES cells have higher ROS levels, dysfunctional mitochondria, shorter telomeres, and telomeric γ-H2A.X foci. We propose that mitochondrial ROS is a major determinant of telomere-dependent senescence at the single-cell level that is responsible for cell-to-cell variation in replicative lifespan.     

Partial proteasome inhibition in human fibroblasts triggers accelerated M1 senescence or M2 crisis depending on p53 and Rb status

Proteasome-dependent degradation has been extensively investigated and has been shown to play a vital role in the maintenance of cellular homeostasis. Proteasome activity and expression are reduced during aging and replicative senescence. Its activation has been shown to confer lifespan extension in human diploid fibroblasts (HDFs), whereas partial proteasome inhibition triggers an irreversible premature senescent state in young HDFs. As p53 and Rb tumor suppressors regulate both replicative and premature senescence (RS and PS, respectively), in this study we investigated their implication in proteasome inhibition-mediated PS. By taking advantage of a variety of HDFs with defective p53 or/and Rb pathways, we reveal that proteasome activity inhibition to levels normally found in senescent human cells results in immediate growth arrest and/or moderate increase of apoptotic death. These effects are independent of the cellular genetic context. However, in the long term, proteasome inhibition-mediated PS can only be initiated and maintained in the presence of functional p53. More specifically, we demonstrate that following partial proteasome inhibition, senescence is dominant in HDFs with functional p53 and Rb molecules, crisis/death is induced in cells with high p53 levels and defective Rb pathway, whereas stress recovery and restoration of normal cycling occurs in cells that lack functional p53. These data reveal the continuous interplay between the integrity of proteasome function, senescence and cell survival.     

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 .     

Nicotinamide Exerts Antioxidative Effects on Senescent Cells

Nicotinamide (NAM) has been shown to suppress reactive oxygen species (ROS) production in primary human fibroblasts, thereby extending their replicative lifespan when added to the medium during long-term cultivation. Based on this finding, NAM is hypothesized to affect cellular senescence progression by keeping ROS accumulation low. In the current study, we asked whether NAM is indeed able to reduce ROS levels and senescence phenotypes in cells undergoing senescence progression and those already in senescence. We employed two different cellular models: MCF-7 cells undergoing senescence progression and human fibroblasts in a state of replicative senescence. In both models, NAM treatment substantially decreased ROS levels. In addition, NAM attenuated the expression of the assessed senescence phenotypes, excluding irreversible growth arrest. N-acetyl cysteine, a potent ROS scavenger, did not have comparable effects in the tested cell types. These data show that NAM has potent antioxidative as well as anti-senescent effects. Moreover, these findings suggest that NAM can reduce cellular deterioration caused by oxidative damage in postmitotic cells in vivo.     

Mammalian SIRT1 limits replicative life span in response to chronic genotoxic stress

The Saccharomyces cerevisiae chromatin silencing factor Sir2 suppresses genomic instability and extends replicative life span. In contrast, we find that mouse embryonic fibroblasts (MEFs) deficient for SIRT1, a mammalian Sir2 homolog, have dramatically increased resistance to replicative senescence. Extended replicative life span of SIRT1-deficient MEFs correlates with enhanced proliferative capacity under conditions of chronic, sublethal oxidative stress. In this context, SIRT1-deficient cells fail to normally upregulate either the p19(ARF) senescence regulator or its downstream target p53. However, upon acute DNA damage or oncogene expression, SIRT1-deficient cells show normal p19(ARF) induction and cell cycle arrest. Together, our findings demonstrate an unexpected SIRT1 function in promoting replicative senescence in response to chronic cellular stress and implicate p19(ARF) as a downstream effector in this pathway.     

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.     

Oxygen free radicals in cell senescence: are they signal transducers?

Oxygen free radicals have a major impact on senescence of primary human cells. In replicative senescence, which is induced by uncapping of telomeres, the rate of telomere shortening is largely determined by telomere-specific accumulation of DNA damage induced by reactive oxygen species (ROS). More intense ROS-generating stressors can induce premature senescence via generation of telomere-independent DNA damage. Interestingly, ROS levels were also elevated when premature senescence was triggered by pathways downstream or independent of DNA damage. This has led to the suggestion that ROS generation could be a specific component of the signalling pathways inducing senescence. However, the available data are compatible with the concept that senescence is triggered as a DNA damage response. ROS appear to be involved as inducers of DNA damage rather than as specific signalling molecules. The upregulation of ROS production often seen in premature senescence might be related to retrograde response initiated by mitochondria.     

Nicotinamide extends replicative lifespan of human cells

We found that an ongoing application of nicotinamide to normal human fibroblasts not only attenuated expression of the aging phenotype but also increased their replicative lifespan, causing a greater than 1.6-fold increase in the number of population doublings. Although nicotinamide by itself does not act as an antioxidant, the cells cultured in the presence of nicotinamide exhibited reduced levels of reactive oxygen species (ROS) and oxidative damage products associated with cellular senescence, and a decelerated telomere shortening rate without a detectable increase in telomerase activity. Furthermore, in the treated cells growing beyond the original Hayflick limit, the levels of p53, p21WAF1, and phospho-Rb proteins were similar to those in actively proliferating cells. The nicotinamide treatment caused a decrease in ATP levels, which was stably maintained until the delayed senescence point. Nicotinamide-treated cells also maintained high mitochondrial membrane potential but a lower respiration rate and superoxide anion level. Taken together, in contrast to its demonstrated pro-aging effect in yeast, nicotinamide extends the lifespan of human fibroblasts, possibly through reduction in mitochondrial activity and ROS production.     

Metformin alleviates human cellular aging by upregulating the endoplasmic reticulum glutathione peroxidase 7

Metformin, an FDA‐approved antidiabetic drug, has been shown to elongate lifespan in animal models. Nevertheless, the effects of metformin on human cells remain unclear. Here, we show that low‐dose metformin treatment extends the lifespan of human diploid fibroblasts and mesenchymal stem cells. We report that a low dose of metformin upregulates the endoplasmic reticulum‐localized glutathione peroxidase 7 (GPx7). GP×7 expression levels are decreased in senescent human cells, and GPx7 depletion results in premature cellular senescence. We also indicate that metformin increases the nuclear accumulation of nuclear factor erythroid 2‐related factor 2 (Nrf2), which binds to the antioxidant response elements in the GPX7 gene promoter to induce its expression. Moreover, the metformin‐Nrf2‐GPx7 pathway delays aging in worms. Our study provides mechanistic insights into the beneficial effects of metformin on human cellular aging and highlights the importance of the Nrf2‐GPx7 pathway in pro‐longevity signaling.     

UVB-induced premature senescence of human diploid skin fibroblasts

In this work, we show that repeated stresses with UVB (290-320 nm) induce stress-induced premature senescence (SIPS) of skin human diploid fibroblasts (HDFs). HDFs at early cumulative population doublings were exposed three or five times to increasing subcytotoxic doses of UVB with one stress per day. After 2 days of recovery, several biomarkers of replicative senescence were established. First, there was an increase in the proportion of cells positive for senescence-associated beta-galactosidase activity. Second, there was a loss of replicative potential as assessed by a very low level of [3H]-thymidine incorporation. Third, the steady-state level of the mRNA of three senescence-associated genes, i.e. fibronectin, osteonectin and SM22, was increased in HDFs at 72 h after three and five exposures to UVB. In conclusion, these results suggest that it is possible to induce SIPS in HDFs after repeated exposures to subcytotoxic doses of UVB. This model could be used to test whether HDFs in UVB-induced premature senescence are able to promote epithelial cell growth and tumorigenesis in skin, as shown recently with HDFs in H(2)O(2)-induced premature senescence.     

Lysine-specific demethylase 2B (KDM2B)-let-7-enhancer of zester homolog 2 (EZH2) pathway regulates cell cycle progression and senescence in primary cells

Sustained expression of the histone demethylase, KDM2B (Ndy1/FBXL10/JHDM1B), bypasses cellular senescence in primary mouse embryonic fibroblasts (MEFs). Here, we show that KDM2B is a conserved regulator of lifespan in multiple primary cell types and defines a program in which this chromatin-modifying enzyme counteracts the senescence-associated down-regulation of the EZH2 histone methyltransferase. Senescence in MEFs epigenetically silences KDM2B and induces the tumor suppressor miRNAs let-7b and miR-101, which target EZH2. Forced expression of KDM2B promotes immortalization by silencing these miRNAs through locus-specific histone H3 K36me2 demethylation, leading to EZH2 up-regulation. Overexpression of let-7b down-regulates EZH2, induces premature senescence, and counteracts immortalization of MEFs driven by KDM2B. The KDM2B-let-7-EZH2 pathway also contributes to the proliferation of immortal Ink4a/Arf null fibroblasts suggesting that, beyond its anti-senescence role in primary cells, this histone-modifying enzyme functions more broadly in the regulation of cellular proliferation.     

Overexpression of apolipoprotein J in human fibroblasts protects against cytotoxicity and premature senescence induced by ethanol and tert-butylhydroperoxide

Human diploid fibroblasts (HDFs) exposed to subcytotoxic stresses under H2O2, tert-butylhydroperoxide (t-BHP), and ethanol (EtOH) undergo stress-induced premature senescence (SIPS) characterized by many biomarkers of HDFs replicative senescence. Among these biomarkers are a growth arrest, an increase in the senescence-associated beta-galactosidase activity, a senescent morphology, an overexpression of p21waf-1 and the subsequent inability to phosphorylate pRb, the presence of the common 4977-bp mitochondrial deletion, and an increase in the steady-state level of several senescence-associated genes such as apolipoprotein J (apo J). Apo J has been described as a survival gene against cytotoxic stress. In order to study whether apo J would be protective against cytotoxicity SIPS and replicative senescence in human fibroblasts, a full-length complementary deoxyribonucleic acid of apo J was transfected into WI-38 HDFs and SV40-transformed WI-38 HDFs. The overexpression of apo J resulted in an increased cell survival after t-BHP and EtOH stresses at cytotoxic concentrations. In addition, when WI-38 HDFs were exposed to 5 subcytotoxic stresses with EtOH or t-BHP, in conditions that were previously shown to induce SIPS, a lower induction of 2 biomarkers of SIPS was observed in HDFs overexpressing apo J. No effect of apo J overexpression was observed on the proliferative life span of HDFs, even if apo J overexpression triggered osteonectin (SPARC) overexpression, which was shown to decrease the mitogenic potential of platelet-derived growth factor but not of other common growth-inducing conditions. Apo J senescence-related overexpression is proposed to have antiapoptotic rather than antiproliferative effects.