DNA replication stress is a determinant of chronological lifespan in budding yeast

The chronological lifespan of eukaryotic organisms is extended by the mutational inactivation of conserved growth-signaling pathways that regulate progression into and through the cell cycle. Here we show that in the budding yeast S. cerevisiae, these and other lifespan-extending conditions, including caloric restriction and osmotic stress, increase the efficiency with which nutrient-depleted cells establish or maintain a cell cycle arrest in G1. Proteins required for efficient G1 arrest and longevity when nutrients are limiting include the DNA replication stress response proteins Mec1 and Rad53. Ectopic expression of CLN3 encoding a G1 cyclin downregulated during nutrient depletion increases the frequency with which nutrient depleted cells arrest growth in S phase instead of G1. Ectopic expression of CLN3 also shortens chronological lifespan in concert with age-dependent increases in genome instability and apoptosis. These findings indicate that replication stress is an important determinant of chronological lifespan in budding yeast. Protection from replication stress by growth-inhibitory effects of caloric restriction, osmotic and other stresses may contribute to hormesis effects on lifespan. Replication stress also likely impacts the longevity of higher eukaryotes, including humans.     

ZRF1 is a novel S6 kinase substrate that drives the senescence programme

The inactivation of S6 kinases mimics several aspects of caloric restriction, including small body size, increased insulin sensitivity and longevity. However, the impact of S6 kinase activity on cellular senescence remains to be established. Here, we show that the constitutive activation of mammalian target of rapamycin complex 1 (mTORC1) by tuberous sclerosis complex (TSC) mutations induces a premature senescence programme in fibroblasts that relies on S6 kinases. To determine novel molecular targets linking S6 kinase activation to the control of senescence, we set up a chemical genetic screen, leading to the identification of the nuclear epigenetic factor ZRF1 (also known as DNAJC2, MIDA1, Mpp11). S6 kinases phosphorylate ZRF1 on Ser47 in cultured cells and in mammalian tissues in vivo. Knock-down of ZRF1 or expression of a phosphorylation mutant is sufficient to blunt the S6 kinase-dependent senescence programme. This is traced by a sharp alteration in p16 levels, the cell cycle inhibitor and a master regulator of senescence. Our findings reveal a mechanism by which nutrient sensing pathways impact on cell senescence through the activation of mTORC1-S6 kinases and the phosphorylation of ZRF1.     

Increased aerobic metabolism is essential for the beneficial effects of caloric restriction on yeast life span

Calorie restriction is a dietary regimen capable of extending life span in a variety of multicellular organisms. A yeast model of calorie restriction has been developed in which limiting the concentration of glucose in the growth media of Saccharomyces cerevisiae leads to enhanced replicative and chronological longevity. Since S. cerevisiae are Crabtree-positive cells that present repression of aerobic catabolism when grown in high glucose concentrations, we investigated if this phenomenon participates in life span regulation in yeast. S. cerevisiae only exhibited an increase in chronological life span when incubated in limited concentrations of glucose. Limitation of galactose, raffinose or glycerol plus ethanol as substrates did not enhance life span. Furthermore, in Kluyveromyces lactis, a Crabtree-negative yeast, glucose limitation did not promote an enhancement of respiratory capacity nor a decrease in reactive oxygen species formation, as is characteristic of conditions of caloric restriction in S. cerevisiae. In addition, K. lactis did not present an increase in longevity when incubated in lower glucose concentrations. Altogether, our results indicate that release from repression of aerobic catabolism is essential for the beneficial effects of glucose limitation in the yeast calorie restriction model. Potential parallels between these changes in yeast and hormonal regulation of respiratory rates in animals are discussed. G. A. Oliveira and E. B. Tahara contributed equally to this work.     

Persistent DNA damage caused by low levels of mitomycin C induces irreversible cell senescence

Mutations of oncogenes and tumor suppressor genes which activate mTOR through several downstream signaling pathways are common to cancer. Activation of mTOR when combined with inhibition of cell cycle progression or DNA replication stress has previously been shown to promote cell senescence. In the present study, we examined the conditions under which human non-small cell lung carcinoma A549 cells can undergo senescence when treated with the DNA alkylating agent mitomycin C (MMC). While exposure of A549 cells to 0.1 or 0.5 µg/ml of MMC led to their arrest in S phase of the cell cycle and subsequent apoptosis, exposure to 0.01 or 0.02 µg/ml for 6 d resulted in induction of cell senescence and near total (0.01 µg/ml) or total (0.02 µg/ml) elimination of their reproductive potential. During exposure to these low concentrations of MMC, the cells demonstrated evidence of DNA replication stress manifested by expression of γH2AX, p21^WAF1 and a very low level of EdU incorporation into DNA. The data are consistent with the notion that enduring DNA replication stress in cells known to have activated oncogenes leads to their senescence. It is reasonable to expect that tumors having constitutive activation of oncogenes triggering mTOR signaling may be particularly predisposed to undergoing senescence following prolonged treatment with low doses of DNA damaging drugs.     

Persistent DNA damage caused by low levels of mitomycin C induces irreversible cell senescence

Mutations of oncogenes and tumor suppressor genes which activate mTOR through several downstream signaling pathways are common to cancer. Activation of mTOR when combined with inhibition of cell cycle progression or DNA replication stress has previously been shown to promote cell senescence. In the present study, we examined the conditions under which human non-small cell lung carcinoma A549 cells can undergo senescence when treated with the DNA alkylating agent mitomycin C (MMC). While exposure of A549 cells to 0.1 or 0.5 µg/ml of MMC led to their arrest in S phase of the cell cycle and subsequent apoptosis, exposure to 0.01 or 0.02 µg/ml for 6 d resulted in induction of cell senescence and near total (0.01 µg/ml) or total (0.02 µg/ml) elimination of their reproductive potential. During exposure to these low concentrations of MMC, the cells demonstrated evidence of DNA replication stress manifested by expression of γH2AX, p21^WAF1 and a very low level of EdU incorporation into DNA. The data are consistent with the notion that enduring DNA replication stress in cells known to have activated oncogenes leads to their senescence. It is reasonable to expect that tumors having constitutive activation of oncogenes triggering mTOR signaling may be particularly predisposed to undergoing senescence following prolonged treatment with low doses of DNA damaging drugs.     

p16(INK4a) suppression by glucose restriction contributes to human cellular lifespan extension through SIRT1-mediated epigenetic and genetic mechanisms

Although caloric restriction (CR) has been shown to increase lifespan in various animal models, the mechanisms underlying this phenomenon have not yet been revealed. We developed an in vitro system to mimic CR by reducing glucose concentration in cell growth medium which excludes metabolic factors and allows assessment of the effects of CR at the cellular and molecular level. We monitored cellular proliferation of normal WI-38, IMR-90 and MRC-5 human lung fibroblasts and found that glucose restriction (GR) can inhibit cellular senescence and significantly extend cellular lifespan compared with cells receiving normal glucose (NG) in the culture medium. Moreover, GR decreased expression of p16(INK4a) (p16), a well-known senescence-related gene, in all of the tested cell lines. Over-expressed p16 resulted in early replicative senescence in glucose-restricted cells suggesting a crucial role of p16 regulation in GR-induced cellular lifespan extension. The decreased expression of p16 was partly due to GR-induced chromatin remodeling through effects on histone acetylation and methylation of the p16 promoter. GR resulted in an increased expression of SIRT1, a NAD-dependent histone deacetylase, which has positive correlation with CR-induced longevity. The elevated SIRT1 was accompanied by enhanced activation of the Akt/p70S6K1 signaling pathway in response to GR. Furthermore, knockdown of SIRT1 abolished GR-induced p16 repression as well as Akt/p70S6K1 activation implying that SIRT1 may affect p16 repression through direct deacetylation effects and indirect regulation of Akt/p70S6K1 signaling. Collectively, these results provide new insights into interactions between epigenetic and genetic mechanisms on CR-induced longevity that may contribute to anti-aging approaches and also provide a general molecular model for studying CR in vitro in mammalian systems.     

Interorganelle signaling is a determinant of longevity in Saccharomyces cerevisiae

Replicative capacity, which is the number of times an individual cell divides, is the measure of longevity in the yeast Saccharomyces cerevisiae. In this study, a process that involves signaling from the mitochondrion to the nucleus, called retrograde regulation, is shown to determine yeast longevity, and its induction resulted in postponed senescence. Activation of retrograde regulation, by genetic and environmental means, correlated with increased replicative capacity in four different S. cerevisiae strains. Deletion of a gene required for the retrograde response, RTG2, eliminated the increased replicative capacity. RAS2, a gene previously shown to influence longevity in yeast, interacts with retrograde regulation in setting yeast longevity. The molecular mechanism of aging elucidated here parallels the results of genetic studies of aging in nematodes and fruit flies, as well as the caloric restriction paradigm in mammals, and it underscores the importance of metabolic regulation in aging, suggesting a general applicability.     

The soma-germline communication: implications for somatic and reproductive aging

Aging is characterized by a functional decline in most physiological processes, including alterations in cellular metabolism and defense mechanisms. Increasing evidence suggests that caloric restriction extends longevity and retards age-related diseases at least in part by reducing metabolic rate and oxidative stress in a variety of species, including yeast, worms, flies, and mice. Moreover, recent studies in invertebrates – worms and flies, highlight the intricate interrelation between reproductive longevity and somatic aging (known as disposable soma theory of aging), which appears to be conserved in vertebrates. This review is specifically focused on how the reproductive system modulates somatic aging and vice versa in genetic model systems. Since many signaling pathways governing the aging process are evolutionarily conserved, similar mechanisms may be involved in controlling soma and reproductive aging in vertebrates.     

Visualization of ribonucleotide reductase catalytic oxidation establishes thioredoxins as its major reductants in yeast

Thioredoxins and/or glutaredoxins assist ribonucleotide reductase, and other such enzymes that require disulfide bond reduction during their catalytic cycle. In Saccharomyces cerevisiae, the presence of either pathway is essential but which of these pathways operates in ribonucleotide reductase reduction and how this function contributes to the pathways' essential nature have not been definitively established. We have identified two in vivo redox forms of the S. cerevisiae ribonucleotide reductase R1 subunit, which correspond to catalytically reduced or oxidized enzymes. Cells lacking thioredoxins, which exhibit an elongated S phase, accumulate R1 in its oxidized form and also contain significantly decreased deoxyribonucleotide levels during the S phase. Overexpressing R1 in these cells increases both the amount of the R1 reduced form and the concentrations of deoxyribonucleotides and accelerates DNA replication. These results establish thioredoxins as the major RNR reducing system in yeast and indicate that impaired RNR reduction accounts for the S phase defects of thioredoxin-deficient cells.     

Cell cycle regulation of ribonucleoside diphosphate reductase activity in permeable mouse L cells and in extracts

Ribonucleoside diphosphate reductase (EC1.17.4.1) was previously characterized in exponentially growing mouse L cells selectively permeabilized to small molecules by treatment with dextran sulfate (Kucera and Paulus, 1982b). This characterization has now been extended to cells in specific phases of the cell cycle and in transition between cell cycle phases, with activity studied both in situ (permeabilized cells) and in cell extracts. Cells at various stages in the cell cycle were obtained by unit-gravity sedimentation employing a commercially available reorienting chamber device, by G1 arrest induced by isoleucine limitation, and by metaphase arrest induced by Colcemid. G1 cells from both cycling and noncycling populations had negligible levels of ribonucleotide reductase activity as measured by CDP reduction both in situ and in extracts. When G1 arrested cells were allowed to progress to S phase, ribonucleotide reductase activity increased in parallel with [3H]thymidine incorporation into DNA. Ribonucleotide reductase activity in extracts increased at a somewhat greater rate than in situ activity. S phase ribonucleotide reductase activity measured in situ resembled the previously characterized activity in exponentially growing cells with respect to an absolute dependence on ATP or its analogs as positive allosteric effector, sensitivity to the negative allosteric effector dATP, and low susceptibility to stimulation by NADPH, dithiothreitol, and FeCl3. Disruption of permeabilized cells caused reductase activity to become highly dependent on the presence of both dithiothreitol and FeCl3. As synchronized cultures progressed from S into G2/M phase, no significant change in ribonucleotide reductase activity was seen. On the other hand, when cells that had been arrested in metaphase by Colcemid were allowed to resume cell cycle traversal by removing the drug, in situ ribonucleotide reductase activity decreased by 75% within 2.5 h. This decrease seemed to be a late mitotic event, since it was not correlated with the percentage of cells entering G1 phase. The cause of a subsequent slight increase of in situ ribonucleotide reductase activity is not clear. Parallel measurements of ribonucleotide reductase activity in cell extracts indicated also an initial decline accompanied by increasing dependence on added dithiols and FeCl3, followed by complete activity loss. Our results suggest a cell cycle pattern of ribonucleotide reductase activity that involves negligible levels in G1 phase, a progressive increase of activity upon entry into S phase paralleling overall DNA synthesis, continued retention of significant ribonucleotide reductase activity well into the metaphase period of mitosis, and a very rapid decline in activity during the later phases of mitosis. The periods of increase and decrease of ribonucleotide reductase activity were accompanied by modulation of the properties of the enzyme as indicated by differential changes in enzyme activity measured in situ and in extracts.     

Doxorubicin and menadione decrease cell proliferation of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> by different mechanisms

The aim of this study was to examine the effect of doxorubicin and menadione on cell proliferation, cell cycle, glutathione concentration, the expression of ribonucleotide reductase, and the Yap1 dependent redox-sensitive pathway in Saccharomyces cerevisiae as a eukaryote cell model. Our data showed that menadione induced cell-cycle arrest in the G₁ phase, decreased intracellular GSH and GSSG concentrations, dose-dependently increased expression of ribonucleotide reductase and the activity of Yap1 pathway. Doxorubicin induced the cell-cycle arrest in G₁ and S phases, increased the GSH and GSSG concentration and the expression of ribonucleotide reductase, and modulated the Yap-dependent pathway activity.     

Liz1p, a Novel Fission Yeast Membrane Protein, Is Required for Normal Cell Division When Ribonucleotide Reductase Is Inhibited

Ribonucleotide reductase activity is required for generating deoxyribonucleotides for DNA replication. Schizosaccharomyces pombe cells lacking ribonucleotide reductase activity arrest during S phase of the cell cycle. In a screen for hydroxyurea-sensitive mutants in S. pombe, we have identified a gene, liz1⁺, which when mutated reveals an additional, previously undescribed role for ribonucleotide reductase activity during mitosis. Inactivation of ribonucleotide reductase, by either hydroxyurea or a cdc22-M45 mutation, causes liz1⁻ cells in G2 to undergo an aberrant mitosis, resulting in chromosome missegregation and late mitotic arrest. liz1⁺ encodes a 514-amino acid protein with strong similarity to a family of transmembrane transporters, and localizes to the plasma membrane of the cell. These results reveal an unexpected G2/M function of ribonucleotide reductase and establish that defects in a transmembrane protein can affect cell cycle progression.     

Ribonucleotide Reductase Activity of Synchronized KB Cells Infected with Herpes Simplex Virus

The replication of herpes simplex virus (HSV) is unimpeded in KB cells which have been blocked in their capacity to synthesize deoxyribonucleic acid (DNA) by high levels of thymidine (TdR). Studies showed that the presence of excess TdR did not prevent host or viral DNA replication in HSV-infected cells. In fact, more cellular DNA was synthesized in infected TdR-blocked cells than in uninfected TdR-blocked cells. This implies that the event which relieved the TdR block was not specific for viral DNA synthesis but allowed some cellular DNA synthesis to occur. These results suggested that HSV has a means to insure a pool of deoxycytidylate derivatives for DNA replication in the presence of excess TdR. We postulated that a viral-induced ribonucleotide reductase was present in the cell after infection which was not inhibited by thymidine triphosphate (TTP). Accordingly, comparable studies of the ribonucleotide reductase found in infected and uninfected KB cells were made. We established conditions that would permit the study of viral-induced enzymes in logarithmically growing KB cells. A twofold stimulation in reductase activity was observed by 3 hr after HSV-infection. Reductase activity in extracts taken from infected cells was less sensitive to inhibition by exogenous (TTP) than the enzyme activity present in uninfected cells. In fact, the enzyme extracted from infected cells functioned at 60% capacity even in the presence of 2 mm TTP. These results support the idea that a viral-induced ribonucleotide reductase is present after HSV infection of KB cells and that this enzyme is relatively insensitive to inhibition by exogenous TTP.     

Alterations in the cyclic AMP signal transduction pathway regulating ribonucleotide reductase gene expression in malignant H-ras transformed cell lines

Ribonucleotide reductase is a highly regulated activity responsible for reducing ribonucleotides to deoxyribonucleotides, which are required for DNA synthesis and DNA repair. We have tested the hypothesis that malignant cell populations contain alterations in signal pathways important in controlling the expression of the two genes that code for ribonucleotide reductase, R1 and R2. A series of radiation and H-ras transformed mouse 10T1/2 cell lines with increasing malignant potential were exposed to stimulators of cAMP synthesis (forskolin and cholera toxin), an inhibitor of cAMP degradation (3-isobutyl-1-methylxanthine) and a biologically stable analogue of cAMP (8-bromo-cAMP). Dramatic elevations in the expression of the R1 and R2 genes at the message and protein levels were observed in malignant metastatic populations, which were not detected in the normal parental cell line or in cells capable of benign tumor formation. These changes in ribonucleotide reductase gene expression occurred without any detectable modifications in the rates of DNA synthesis, showing that they were regulated by a novel mechanism independent of the S phase of the cell cycle. Furthermore, studies with forskolin (a stimulator of the protein kinase A signal pathway) and the tumor promoter 12–0-tetradecanoylphorbol-13-acetate (a stimulator of the protein kinase C signal pathway), alone or in combination, indicated that their effects on R1 and R2 gene expression in a highly malignant cell line were greater than when they were tested individually, suggesting that the two pathways modulating R1 and R2 gene expression can cooperate to regulate ribonucleotide reduction, and interestingly this can occur in a synergistic fashion. Also, a direct relationship between H-ras expression and ribonucleotide reductase gene expression was observed; analysis of forskolin mediated elevations in R1 and R2 message levels closely correlated with the levels of H-ras expression in the various cell lines. In total, these studies demonstrate that ribonucleotide reductase expression is controlled by a complex process, and malignant ras transformed cells contain alterations in the regulation of signal transduction pathways that lead to novel modifications in ribonucleotide reductase gene expression. This signal mechanism, which is aberrantly regulated in malignant cells, may be related to regulatory pathways involved in determining ribonucleotide reductase expression in a S phase independent manner during periods of DNA repair. © 1994 Wiley-Liss, Inc.     

Caloric restriction and its mimetics

Caloric restriction is the most reliable intervention to prevent age-related disorders and extend lifespan. The reduction of calories by 10-30% compared to an ad libitum diet is known to extend the longevity of various species from yeast to rodents. The underlying mechanisms by which the benefits of caloric restriction occur have not yet been clearly defined. However, many studies are being conducted in an attempt to elucidate these mechanisms, and there are indications that the benefits of caloric restriction are related to alteration of the metabolic rate and the accumulation of reactive oxygen species. During molecular signaling, insulin/insulin-like growth factor signaling, target of rapamycin pathway, adenosine monophosphate activated protein kinase signaling, and Sirtuin are focused as underlying pathways that mediate the benefits of caloric restriction. Here, we will review the current status of caloric restriction. [BMB Reports 2013; 46(4): 181-187]     

热量限制延缓人二倍体成纤维细胞衰老的体外模型

为建立人二倍体成纤维细胞IMR 90的热量限制体外模型 ,分别采用低浓度、正常浓度和高浓度葡萄糖培养条件 ,常规传代培养IMR 90细胞 ,利用综合细胞衰老指标对模型进行评价 .低、正常和高浓度葡萄糖培养条件组IMR 90细胞平均寿限分别为 5 8 3、5 5 0和 4 7 2PDL(群体倍增水平 ) .低浓度葡萄糖培养IMR 90细胞早期增长速度有所减慢 ,但仍保持对生长因子诱导的细胞增殖能力 ,并使晚期IMR 90处于细胞周期S期的比例以及其DNA修复能力显著高于其他条件培养的晚期细胞 .低浓度葡萄糖培养IMR 90晚期细胞的半乳糖苷酶染色阳性率亦明显低于其他条件培养的晚期细胞 .实验结果表明 ,低浓度葡萄糖培养可以延缓IMR 90复制衰老 ,建立了热量限制延缓衰老体外模型 ,为进一步探讨热量限制延缓衰老作用机制的研究打下基础     

Identification of novel factors involved in or regulating initiation of DNA replication by a genome-wide phenotypic screen in Saccharomyces cerevisiae

DNA replication in eukaryotic cells is tightly regulated to ensure faithful inheritance of the genetic material. While the replicators, replication origins and many replication-initiation proteins in Saccharomyces cerevisiae have been identified and extensively studied, the detailed mechanism that controls the initiation of DNA replication is still not well understood. It is likely that some factors involved in or regulating the initiation of DNA replication have not been discovered. To identify novel DNA replication-initiation proteins and their regulators, we developed a sensitive and comprehensive phenotypic screen by combining several established genetic strategies including plasmid loss assays with plasmids containing a single versus multiple replication origins and colony color sectoring assays. We isolated dozen of mutants in previously known initiation proteins and identified several novel factors, including Ctf1p Ctf3p, Ctf4p, Ctf18p, Adk1p and Cdc60p, whose mutants lose plasmid containing a single replication origin at high rates but lose plasmid carrying multiple replication origins at lower rates. We also show that overexpression of replication initiation proteins causes synthetic dosage lethality or growth defects in ctf1 and ctf18 mutants and that Ctf1p and Ctf18p physically interact with ORC, Cdt1p and MCM proteins. Furthermore, depletion of both Ctf1p and Ctf18p prevents S phase entry, retards S phase progression, and reduces pre-RC formation during the M-to-G1 transition. These data suggest that Ctf1p and Ctf18p together play important roles in regulating the initiation of DNA replication.     

The S‐phase checkpoint: targeting the replication fork

The S‐phase checkpoint is a surveillance mechanism, mediated by the protein kinases Mec1 and Rad53 in the budding yeast Saccharomyces cerevisiae (ATR and Chk2 in human cells, respectively) that responds to DNA damage and replication perturbations by co‐ordinating a global cellular response necessary to maintain genome integrity. A key aspect of this response is the stabilization of DNA replication forks, which is critical for cell survival. A defective checkpoint causes irreversible replication‐fork collapse and leads to genomic instability, a hallmark of cancer cells. Although the precise mechanisms by which Mec1/Rad53 maintain functional replication forks are currently unclear, our knowledge about this checkpoint function has significantly increased during the last years. Focusing mainly on the advances obtained in S. cerevisiae, the present review will summarize our understanding of how the S‐phase checkpoint preserves the integrity of DNA replication forks and discuss the most recent findings on this topic.     

Postmitotic neurons develop a p21‐dependent senescence‐like phenotype driven by a DNA damage response

In senescent cells, a DNA damage response drives not only irreversible loss of replicative capacity but also production and secretion of reactive oxygen species (ROS) and bioactive peptides including pro‐inflammatory cytokines. This makes senescent cells a potential cause of tissue functional decline in aging. To our knowledge, we show here for the first time evidence suggesting that DNA damage induces a senescence‐like state in mature postmitotic neurons in vivo. About 40–80% of Purkinje neurons and 20–40% of cortical, hippocampal and peripheral neurons in the myenteric plexus from old C57Bl/6 mice showed severe DNA damage, activated p38MAPkinase, high ROS production and oxidative damage, interleukin IL‐6 production, heterochromatinization and senescence‐associated β‐galactosidase activity. Frequencies of these senescence‐like neurons increased with age. Short‐term caloric restriction tended to decrease frequencies of positive cells. The phenotype was aggravated in brains of late‐generation TERC?/? mice with dysfunctional telomeres. It was fully rescued by loss of p21(CDKN1A) function in late‐generation TERC?/?CDKN1A?/? mice, indicating p21 as the necessary signal transducer between DNA damage response and senescence‐like phenotype in neurons, as in senescing fibroblasts and other proliferation‐competent cells. We conclude that a senescence‐like phenotype is possibly not restricted to proliferation‐competent cells. Rather, dysfunctional telomeres and/or accumulated DNA damage can induce a DNA damage response leading to a phenotype in postmitotic neurons that resembles cell senescence in multiple features. Senescence‐like neurons might be a source of oxidative and inflammatory stress and a contributor to brain aging.