Methionine restriction slows down senescence in human diploid fibroblasts

Methionine restriction (MetR) extends lifespan in animal models including rodents. Using human diploid fibroblasts (HDF), we report here that MetR significantly extends their replicative lifespan, thereby postponing cellular senescence. MetR significantly decreased activity of mitochondrial complex IV and diminished the accumulation of reactive oxygen species. Lifespan extension was accompanied by a significant decrease in the levels of subunits of mitochondrial complex IV, but also complex I, which was due to a decreased translation rate of several mtDNA‐encoded subunits. Together, these findings indicate that MetR slows down aging in human cells by modulating mitochondrial protein synthesis and respiratory chain assembly.     

Snake venoms promote stress-induced senescence in human fibroblasts

Snake venoms are widely studied in terms of their systemic toxicity and proteolytic, hemotoxic, neurotoxic, and cytotoxic activities. However, little is known about snake-venom-mediated effects when used at low, noncytotoxic concentrations. In the current study, two human fibroblast cell lines of different origin, namely WI-38 fetal lung fibroblasts and BJ foreskin fibroblasts were used to investigate snake-venom-induced adaptive response at a relatively noncytotoxic concentration (0.01 µg/ml). The venoms of Indochinese spitting cobra ( Naja siamensis), western green mamba ( Dendroaspis viridis), forest cobra ( Naja melanoleuca), and southern copperhead ( Agkistrodon contortrix) were considered. Snake venoms promoted FOXO3a-mediated oxidative stress response and to a lesser extent DNA damage response, which lead to changes in cell cycle regulators both at messenger RNA and protein levels, limited cell proliferation and migration, and induced cellular senescence. Taken together, we have shown for the first time that selected snake venoms may also exert adverse effects when used at relatively noncytotoxic concentrations.     

Small molecule compounds that induce cellular senescence

To date, dozens of stress‐induced cellular senescence phenotypes have been reported. These cellular senescence states may differ substantially from each other, as well as from replicative senescence through the presence of specific senescence features. Here, we attempted to catalog virtually all of the cellular senescence‐like states that can be induced by low molecular weight compounds. We summarized biological markers, molecular pathways involved in senescence establishment, and specific traits of cellular senescence states induced by more than fifty small molecule compounds.     

Bacterial intoxication evokes cellular senescence with persistent DNA damage and cytokine signalling

Cytolethal distending toxins (CDTs) are proteins produced and secreted by facultative pathogenic strains of Gram-negative bacteria with potentially genotoxic effects. Mammalian cells exposed to CDTs undergo cell type-dependent cell-cycle arrest or apoptosis; however, the cell fate responses to such intoxication are mechanistically incompletely understood. Here we show that both normal and cancer cells (BJ, IMR-90 and WI-38 fibroblasts, HeLa and U2-OS cell lines) that survive the acute phase of intoxication by Haemophilus ducreyi CDT possess the hallmarks of cellular senescence. This characteristic phenotype included persistently activated DNA damage signalling (detected as 53BP1/γH2AX⁺ foci), enhanced senescence-associated β-galactosidase activity, expansion of promyelocytic leukaemia nuclear compartments and induced expression of several cytokines (especially interleukins IL-6, IL-8 and IL-24), overall features shared by cells undergoing replicative or premature cellular senescence. We conclude that analogous to oncogenic, oxidative and replicative stresses, bacterial intoxication represents another pathophysiological stimulus that induces premature senescence, an intrinsic cellular response that may mechanistically underlie the 'distended' morphology evoked by CDTs. Finally, the activation of the two anticancer barriers, apoptosis and cellular senescence, together with evidence of chromosomal aberrations (micronucleation) reported here, support the emerging genotoxic and potentially oncogenic effects of this group of bacterial toxins, and warrant further investigation of their role(s) in human disease.     

Restoration of senescent human diploid fibroblasts by modulation of the extracellular matrix

Human diploid fibroblasts have the capacity to complete a finite number of cell divisions before entering a state of replicative senescence characterized by growth arrest, changes in morphology, and altered gene expression. Herein, we report that interaction with extracellular matrix (ECM) from young cells is sufficient to restore aged, senescent cells to an apparently youthful state. The identity of the restored cells as having been derived from senescent cells has been confirmed by a variety of methods, including time lapse live cell imaging and DNA finger print analysis. In addition to cell morphology, phenotypic restoration was assessed by resumption of proliferative potential, growth factor responsiveness, reduction of intracellular reactive oxygen species levels, recovery of mitochondrial membrane potential, and increased telomere length. Mechanistically, we find that both Ku and SIRT1 are induced during restoration and are required for senescent cells to return to a youthful phenotype. These observations demonstrate that human cellular senescence is profoundly influenced by cues from the ECM, and that senescent cell plasticity is much greater than that was previously believed to be the case.     

Effect of cell cycle inhibitor p19ARF on senescence of human diploid cell

To investigate the effect of cell cycle inhibitor p19ARF on replicative senescence of human diploid cell,recombinant p19ARF eukaryotic expression vector was constructed and p19ARF gene was transfected into human diploid fibroblasts (WI-38 cells) by liposome-mediated transfection for overexpression.Then, the effects of p19ARF on replicative senescence of WI-38 cells were observed. The results revealed that, compared with control cells, the WI-38 cells in which p19ARFgene was introduced showed significant up-regulation of p53 and p21 expression level, decrease of cell generation by 10-12 generations, decline of cell growth rate with cell cycle being arrested at G1 phase, increase of positive rate of senescent marker SA-β-gal staining, and decrease of mitochondrial membrane potential. The morphology of the transfected fibroblasts presented the characteristics changes similar to senescent cells.These results indicated that high expression of p19ARF may promote the senescent process of human diploid cells.     

Effect of cell cycle inhibitor p19ARF on senescence of human diploid cell

To investigate the effect of cell cycle inhibitor p19ARF on replicative senescence of human diploid cell, recombinant p19ARF eukaryotic expression vector was constructed and p19ARF gene was transfected into human diploid fibroblasts (WI-38 cells) by liposome-mediated transfection for overexpression. Then, the effects of p19ARF on replicative senescence of WI-38 cells were observed. The results re- vealed that, compared with control cells, the WI-38 cells in which p19ARF gene was introduced showed significant up-regulation of p53 and p21 expression level, decrease of cell generation by 10 12 generations, decline of cell growth rate with cell cycle being arrested at G1 phase, increase of positive rate of senescent marker SA-β-gal staining, and decrease of mitochondrial membrane potential. The morphology of the transfected fibroblasts presented the characteristics changes similar to senescent cells. These results indicated that high expression of p19ARF may promote the senescent process of human diploid cells.     

Identification of a small molecule SR9009 that activates NRF2 to counteract cellular senescence

The senescence‐associated secretory phenotype (SASP) is a striking characteristic of senescence. Accumulation of SASP factors causes a pro‐inflammatory response linked to chronic disease. Suppressing senescence and SASP represents a strategy to prevent or control senescence‐associated diseases. Here, we identified a small molecule SR9009 as a potent SASP suppressor in therapy‐induced senescence (TIS) and oncogene‐induced senescence (OIS). The mechanism studies revealed that SR9009 inhibits the SASP and full DNA damage response (DDR) activation through the activation of the NRF2 pathway, thereby decreasing the ROS level by regulating the expression of antioxidant enzymes. We further identified that SR9009 effectively prevents cellular senescence and suppresses the SASP in the livers of both radiation‐induced and oncogene‐induced senescence mouse models, leading to alleviation of immune cell infiltration. Taken together, our findings suggested that SR9009 prevents cellular senescence via the NRF2 pathway in vitro and in vivo, and activation of NRF2 may be a novel therapeutic strategy for preventing cellular senescence.     

Five dysfunctional telomeres predict onset of senescence in human cells

Replicative senescence is accompanied by a telomere-specific DNA damage response (DDR). We found that DDR+ telomeres occur spontaneously in early-passage normal human cells and increase in number with increasing cumulative cell divisions. DDR+ telomeres at replicative senescence retain TRF2 and RAP1 proteins, are not associated with end-to-end fusions and mostly result from strand-independent, postreplicative dysfunction. On the basis of the calculated number of DDR+ telomeres in G1-phase cells just before senescence and after bypassing senescence by inactivation of wild-type p53 function, we conclude that the accrual of five telomeres in G1 that are DDR+ but nonfusogenic is associated with p53-dependent senescence.     

MAPK15 protects from oxidative stress‐dependent cellular senescence by inducing the mitophagic process

Mitochondria are the major source of reactive oxygen species (ROS), whose aberrant production by dysfunctional mitochondria leads to oxidative stress, thus contributing to aging as well as neurodegenerative disorders and cancer. Cells efficiently eliminate damaged mitochondria through a selective type of autophagy, named mitophagy. Here, we demonstrate the involvement of the atypical MAP kinase family member MAPK15 in cellular senescence, by preserving mitochondrial quality, thanks to its ability to control mitophagy and, therefore, prevent oxidative stress. We indeed demonstrate that reduced MAPK15 expression strongly decreases mitochondrial respiration and ATP production, while increasing mitochondrial ROS levels. We show that MAPK15 controls the mitophagic process by stimulating ULK1‐dependent PRKN Ser¹⁰⁸ phosphorylation and inducing the recruitment of damaged mitochondria to autophagosomal and lysosomal compartments, thus leading to a reduction of their mass, but also by participating in the reorganization of the mitochondrial network that usually anticipates their disposal. Consequently, MAPK15‐dependent mitophagy protects cells from accumulating nuclear DNA damage due to mitochondrial ROS and, consequently, from senescence deriving from this chronic DNA insult. Indeed, we ultimately demonstrate that MAPK15 protects primary human airway epithelial cells from senescence, establishing a new specific role for MAPK15 in controlling mitochondrial fitness by efficient disposal of old and damaged organelles and suggesting this kinase as a new potential therapeutic target in diverse age‐associated human diseases.     

DNA damage response and cellular senescence in tissues of aging mice

The impact of cellular senescence onto aging of organisms is not fully clear, not at least because of the scarcity of reliable data on the mere frequency of senescent cells in aging tissues. Activation of a DNA damage response including formation of DNA damage foci containing activated H2A.X (γ-H2A.X) at either uncapped telomeres or persistent DNA strand breaks is the major trigger of cell senescence. Therefore, γ-H2A.X immunohistochemistry (IHC) was established by us as a reliable quantitative indicator of senescence in fibroblasts in vitro and in hepatocytes in vivo and the age dependency of DNA damage foci accumulation in ten organs of C57Bl6 mice was analysed over an age range from 12 to 42 months. There were significant increases with age in the frequency of foci-containing cells in lung, spleen, dermis, liver and gut epithelium. In liver, foci-positive cells were preferentially found in the centrilobular area, which is exposed to higher levels of oxidative stress. Foci formation in the intestine was restricted to the crypts. It was not associated with either apoptosis or hyperproliferation. That telomeres shortened with age in both crypt and villus enterocytes, but telomeres in the crypt epithelium were longer than those in villi at all ages were confirmed by us. Still, there was no more than random co-localization between γ-H2A.X foci and telomeres even in crypts from very old mice, indicating that senescence in the crypt enterocytes is telomere independent. The results suggest that stress-dependent cell senescence could play a causal role for aging of mice.     

Cardiolipin induces premature senescence in normal human fibroblasts

Lipids seem to have various roles in cellular senescence. We found that cardiolipin very sensitively inhibits growth of normal human fibroblasts, whereas other phospholipids do not at 100 times higher concentrations. Growth arrested cells showed morphology similar to those of normally senesced cells and strongly induced senescence-associated beta-galactosidase. Senescence markers such as the p21(waf1/sdi-1), fibronectin, and collagenase-I genes were significantly upregulated by cardiolipin. In addition, caldiolipin significantly increased in normally senesced human fibroblasts leaving other phospholipids unaltered. These results suggest that accumulation of cardiolipin is one of the causes for replicative senescence.     

Emerging roles of extracellular vesicles in cellular senescence and aging

Cellular senescence is a cellular program that prevents the proliferation of cells at risk of neoplastic transformation. On the other hand, age‐related accumulation of senescent cells promotes aging at least partially due to the senescence‐associated secretory phenotype, whereby cells secrete high levels of inflammatory cytokines, chemokines, and matrix metalloproteinases. Emerging evidence, however, indicates that extracellular vesicles (EVs) are important mediators of the effects of senescent cells on their microenvironment. Senescent cells secrete more EphA2 and DNA via EVs, which can promote cancer cell proliferation and inflammation, respectively. Extracellular vesicles secreted from DNA‐damaged cells can also affect telomere regulation. Furthermore, it has now become clear that EVs actually play important roles in many aspects of aging. This review is intended to summarize these recent progresses, with emphasis on relationships between cellular senescence and EVs.     

Monitoring of cellular senescence by DNA-methylation at specific CpG sites

Replicative senescence has fundamental implications on cell morphology, proliferation, and differentiation potential. Here, we describe a simple method to track long-term culture based on continuous DNA-methylation changes at six specific CpG sites. This epigenetic senescence signature can be used as biomarker for various cell types to predict the state of cellular senescence with regard to the number of passages, population doublings, or days of in vitro culture.     

细胞衰老与细胞自噬的生物学关联及其意义

细胞衰老是指细胞生理功能的衰减,包括增殖能力下降、细胞周期停滞、对促凋亡应激不敏感、衰老相关基因和蛋白表达增加,伴有形态学衰老改变,渐趋死亡的现象,其至少可分为复制性衰老和应激诱导的衰老。细胞自噬属于细胞＂自食＂现象,是细胞依赖溶酶体的分解代谢过程,能降解受损蛋白、衰老或损伤的细胞器等细胞结构,可被多种应激所触发。细胞自噬的典型特征是形成自噬体并呈递给溶酶体,该过程在蛋白质和细胞器质量控制中起基础作用并维持了细胞能量的稳态。最新研究表明,自噬与细胞衰老密切相关,参与蛋白酶和自噬相关调节的BAG蛋白家族中BAG3/BAG1比值在复制性衰老时增高,且BAG3在细胞衰老时能介导自噬的激活。在Ras诱导的细胞衰老进程中亦可观察到较高的自噬活性。再者,自噬作为生物机体抗衰老的效应因子的遗传学证据已在低等真核生物中发现。还有研究证实,作为人类精液主要组分的亚精胺能够触发组蛋白H3脱乙酰基作用,此改变上调了自噬相关转录物的表达,继而引发自噬活性增强,从而延缓了多种细胞的衰老进程。另有研究显示,在P53/Arf的正常调节下,小鼠的衰老进程得以延缓,而Arf在细胞自噬过程的调节中亦是不可或缺的。总之,自噬活性的改变影响细胞衰老进程并可作为细胞衰老新的效应机理。