Hydroxyurea induces a senescence-like change of K562 human erythroleukemia cell

Hydroxyurea, a differentiation-inducing agent of human erythroleukemia K562 cells, is commonly used to treat some types of leukemia. However, the mechanism for its therapeutic effect is not clearly understood yet. In this study, we have observed an interesting effect of hydroxyurea on tumor cells: an induction of senescence-like changes. Human erythroleukemia K562 cells, when treated with hydroxyurea for 7 days or more, underwent a change into phenotypically senescent cells together with a reduction of hemoglobin generation, a differentiation marker. The hydroxyurea-treated cells showed positive senescence associated-beta-galactosidase staining, a senescence index, and the accumulation of cdk (cyclin dependent kinase) inhibitors, such as p16INK4a, p21Waf1, and p27Kip1, implicated in cellular senescence. Nonetheless, these changes were not accompanied by DNA fragmentation. Taken together, we summarize that the long-term treatment of cancer cells with hydroxyurea can induce cellular senescence different from differentiation or programmed cell death.     

Reprogramming of replicative senescence in hepatocellular carcinoma-derived cells

Tumor cells have the capacity to proliferate indefinitely that is qualified as replicative immortality. This ability contrasts with the intrinsic control of the number of cell divisions in human somatic tissues by a mechanism called replicative senescence. Replicative immortality is acquired by inactivation of p53 and p16INK4a genes and reactivation of hTERT gene expression. It is unknown whether the cancer cell replicative immortality is reversible. Here, we show the spontaneous induction of replicative senescence in p53-and p16INK4a-deficient hepatocellular carcinoma cells. This phenomenon is characterized with hTERT repression, telomere shortening, senescence arrest, and tumor suppression. SIP1 gene (ZFHX1B) is partly responsible for replicative senescence, because short hairpin RNA-mediated SIP1 inactivation released hTERT repression and rescued clonal hepatocellular carcinoma cells from senescence arrest.     

Id1 cooperates with oncogenic Ras to induce metastatic mammary carcinoma by subversion of the cellular senescence response

Recent evidence demonstrates that senescence acts as a barrier to tumorigenesis in response to oncogene activation. Using a mouse model of breast cancer, we tested the importance of the senescence response in solid cancer and identified genetic pathways regulating this response. Mammary expression of activated Ras led to the formation of senescent cellular foci in a majority of mice. Deletion of the p19(ARF), p53, or p21(WAF1) tumor suppressors but not p16(INK4a) prevented senescence and permitted tumorigenesis. Id1 has been implicated in the control of senescence in vitro, and elevated expression of Id1 is found in a number of solid cancers, so we tested whether overexpression of Id1 regulates senescence in vivo. Although overexpression of Id1 in the mammary epithelium was not sufficient for tumorigenesis, mice with expression of both Id1 and activated Ras developed metastatic cancer. These tumors expressed high levels of p19(Arf), p53, and p21(Waf1), demonstrating that Id1 acts to make cells refractory to p21(Waf1)-dependent cell cycle arrest. Inactivation of the conditional Id1 allele in established tumors led to widespread senescence within 10 days, tumor growth arrest, and tumor regression in 40% of mice. Mice in which Id1 expression was inactivated also exhibited greatly reduced pulmonary metastatic load. These data demonstrate that established tumors remain sensitive to senescence and that Id1 may be a valuable target for therapy.     

Activation of p38 MAP kinase and stress signalling in fibroblasts from the progeroid Rothmund–Thomson syndrome

Rothmund–Thomson fibroblasts had replicative lifespans and growth rates within the range for normal fibroblasts; however, they show elevated levels of the stress-associated p38 MAP kinase, suggestive of stress during growth. Treatment with the p38 MAP kinase inhibitor SB203580 increased both lifespan and growth rate, as did reduction of oxidative stress using low oxygen in some strains. At replicative senescence p53, p21^WAF1 and p16^INK4A levels were elevated, and abrogation of p53 using shRNA knockdown allowed the cells to bypass senescence. Ectopic expression of human telomerase allowed Rothmund–Thomson fibroblasts to bypass senescence. However, activated p38 was still present, and continuous growth for some telomerised clones required either a reduction in oxidative stress or SB203580 treatment. Overall, the evidence suggests that replicative senescence in Rothmund–Thomson cells resembles normal senescence in that it is telomere driven and p53 dependent. However, the lack of RECQL4 leads to enhanced levels of stress during cell growth that may lead to moderate levels of stress-induced premature senescence. As replicative senescence is believed to underlie human ageing, a moderate level of stress-induced premature senescence and p38 activity may play a role in the relatively mild ageing phenotype seen in Rothmund–Thomson.

Electronic supplementary material

The online version of this article (doi:10.1007/s11357-012-9476-9) contains supplementary material, which is available to authorized users.     

Continuous elimination of oxidized nucleotides is necessary to prevent rapid onset of cellular senescence

Reactive oxygen species (ROS) appear to play a role in limiting both cellular and organismic lifespan. However, because of their pleiotropic effects, it has been difficult to ascribe a specific role to ROS in initiating the process of cellular senescence. We have studied the effects of oxidative DNA damage on cell proliferation, believing that such damage is of central importance to triggering senescence. To do so, we devised a strategy to decouple levels of 8-oxoguanine, a major oxidative DNA lesion, from ROS levels. Suppression of MTH1 expression, which hydrolyzes 8-oxo-dGTP, was accompanied by increased total cellular 8-oxoguanine levels and caused early-passage primary and telomerase-immortalized human skin fibroblasts to rapidly undergo senescence, doing so without altering cellular ROS levels. This senescent phenotype recapitulated several salient features of replicative senescence, notably the presence of senescence-associated beta-galactosidase (SA beta-gal) activity, apparently irreparable genomic DNA breaks, and elevation of p21^Cip1, p53, and p16^INK4A tumor suppressor protein levels. Culturing cells under low oxygen tension (3%) largely prevented the shMTH1-dependent senescent phenotype. These results indicate that the nucleotide pool is a critical target of intracellular ROS and that oxidized nucleotides, unless continuously eliminated, can rapidly induce cell senescence through signaling pathways very similar to those activated during replicative senescence.     

Oncogenic ras induces premature senescence in endothelial cells: role of p21(Cip1/Waf1)

Recent studies have shown that the presence of tumor suppressors such as p53 or p16 account for the lack of transformation in primary cells. To investigate a potential role of active Ras in atherosclerosis, we infected bovine aortic endothelial cells with a replication-deficient, recombinant adenovirus containing the activated H-Ras^61L gene. Ras overexpression led after 72 hours to G1- and G2/M-cell cycle arrest due to induction of p21^Cip1/Waf1. Treatment of Ras-infected endothelial cells with 40 ng/ml TNF-α for 20 hours augmented apoptosis 8-fold in comparison to Ad-Con (control virus with empty expression cassette) infected cells (36.2 % vs. 4.3 %, p < 0.001), while Ras itself did not cause any cell death. Furthermore, more than 58 % of Ras-infected cells stained positive for senescence-associated β-galactosidase activity as opposed to 2 % in control vector-infected cells (p < 0.001), strongly suggesting a senescent phenotype in the Ras-infected population. We found further features of senescence in Ras-transduced endothelial cells, such as growth arrest and the lack of AP-1 serum inducibility. Finally, we evaluated the role of p21^Cip1/Waf1 in this process of senescence. Adenoviral overexpression of p21 led to growth arrest by induction of G1- and G2/M-cell cycle arrest. In addition, p21-overexpressing endothelial cells were highly sensitive for TNF-α induced-apoptosis. Surprisingly, senescence-associated β-galactosidase activity was not apparant in p21-infected endothelial cells, suggesting further signaling events necessary for the senescent morphology of endothelial cells. Our results demonstrate a novel way to render primary endothelial cells senescent by overexpressing oncogenic Ras. Increased sensitivity of senescent endothelial cells for cytotoxic stimuli seemed to be due to Ras-induced upregulation of p21^Cip1/Waf1. Future studies have to investigate a potential role of Ras in human vascular biology. Received: 5 June 2001, Returned for revision: 28 June 2001, Revision received: 6 July 2001, Accepted: 31 July 2001     

Sustained inhibition of oxidative phosphorylation impairs cell proliferation and induces premature senescence in human fibroblasts

The mitochondrial theory of aging predicts that functional alterations in mitochondria contribute to the aging process. Whereas this hypothesis implicates increased production of reactive oxygen species (ROS) as a driving force of the aging process, little is known about molecular mechanisms by which mitochondrial impairment might contribute to aging. Using cellular senescence as a model for human aging, we have recently reported partial uncoupling of the respiratory chain in senescent human fibroblasts. In the present communication, we address a potential cause-effect relationship between mitochondrial impairment and the appearance of a senescence-like phenotype in young cells. We found that treatment by antimycin A delays proliferation and induces premature senescence in a subset of the cells, associated with increased reactive oxygen species (ROS) production. Quenching of ROS by antioxidants did however not restore proliferation capacity nor prevent premature senescence. Premature senescence is also induced upon chronic exposure to oligomycin, irrespective of ROS production, and oligomycin treatment induced the up-regulation of the cdk inhibitors p16, p21 and p27, which are also up-regulated in replicative senescence. Thus, besides the well-established influence of ROS on proliferation and senescence, a reduction in the level of oxidative phosphorylation is causally related to reduced cell proliferation and the induction of premature senescence.     

Involvement of the cyclin-dependent kinase inhibitor p16 (INK4a) in replicative senescence of normal human fibroblasts

Human diploid fibroblasts (HDFs) can be grown in culture for a finite number of population doublings before they cease proliferation and enter a growth-arrest state termed replicative senescence. The retinoblastoma gene product, Rb, expressed in these cells is hypophosphorylated. To determine a possible mechanism by which senescent human fibroblasts maintain a hypophosphorylated Rb, we examined the expression levels and interaction of the Rb kinases, CDK4 and CDK6, and the cyclin-dependent kinase inhibitors p21 and p16 in senescent HDFs. Cellular p21 protein expression increased dramatically during the final two to three passages when the majority of cells lost their growth potential and neared senescence but p21 levels declined in senescent HDFs. During this period, p16 mRNA and cellular protein levels gradually rose with the protein levels in senescent HDFs reaching nearly 40-fold higher than early passage cells. In senescent HDFs, p16 was shown to be complexed to both CDK4 and CDK6. Immunodepletion analysis of p21 and p16 from the senescent cell extracts revealed that p16 is the major CDK inhibitor for both CDK4 and CDK6 kinases. Immunoprecipitation of CDK4 and CDK6 and their associated proteins from radiolabeled extracts from senescent HDFs showed no other CDK inhibitors. Based upon these results, we propose that senescence is a multistep process requiring the expression of both p21 and p16. p16 up-regulation is a key event in the terminal stages of growth arrest in senescence, which may explain why p16 but not p21 is commonly mutated in immortal cells and human tumors.     

Telomere shortening in the damaged small bile ducts in primary biliary cirrhosis reflects ongoing cellular senescence

Telomere shortening is a trigger of cellular senescence. Biliary epithelial cells in damaged small bile ducts in primary biliary cirrhosis (PBC) show senescent features such as the expression of senescence-associated beta-galactosidase and the increased expression of p16(INK4a) and p21(WAF1/Cip1). We investigated whether the telomere shortening is involved in the pathogenesis of biliary cellular senescence in PBC. We analyzed the telomere length of biliary epithelial cells using quantitative fluorescence in situ hybridization in livers taken from the patients with PBC (n = 13) and control livers (n = 13). We also assessed immunohistochemically the prevalence of DNA damage and the expression of p16(INK4a) and p21(WAF1/Cip1). The study showed a significant decrease in telomere length in biliary epithelial cells in the damaged small bile ducts and bile ductules in PBC compared with normal-looking bile ducts and bile ductules in PBC, chronic viral hepatitis, and normal livers (P < 0.01). gammaH2AX-DNA-damage-foci were detected in biliary epithelial cells in damaged small bile ducts and bile ductules in PBC but were absent in biliary epithelial cells in chronic viral hepatitis and normal livers. The expression of p16(INK4a) and p21(WAF1/Cip1) was increased corresponding to telomere shortening and gammaH2AX-DNA-damage-foci in the damaged small bile ducts in PBC. CONCLUSION: Telomere shortening and an accumulation of DNA damage coincide with increased expression of p16(INK4a) and p21(WAF1/Cip1) in the damaged bile ducts, characterize biliary cellular senescence, and may play a role in the following progressive bile duct loss in PBC.     

Hypoxia suppresses conversion from proliferative arrest to cellular senescence

Unlike reversible quiescence, cellular senescence is characterized by a large flat cell morphology, β-gal staining and irreversible loss of regenerative (i.e., replicative) potential. Conversion from proliferative arrest to irreversible senescence, a process named geroconversion, is driven in part by growth-promoting pathways such as mammalian target of rapamycin (mTOR). During cell cycle arrest, mTOR converts reversible arrest into senescence. Inhibitors of mTOR can suppress geroconversion, maintaining quiescence instead. It was shown that hypoxia inhibits mTOR. Therefore, we suggest that hypoxia may suppress geroconversion. Here we tested this hypothesis. In HT-p21-9 cells, expression of inducible p21 caused cell cycle arrest without inhibiting mTOR, leading to senescence. Hypoxia did not prevent p21 induction and proliferative arrest, but instead inhibited the mTOR pathway and geroconversion. Exposure to hypoxia during p21 induction prevented senescent morphology and loss of regenerative potential, thus maintaining reversible quiescence so cells could restart proliferation after switching p21 off. Suppression of geroconversion was p53- and HIF-1-independent, as hypoxia also suppressed geroconversion in cells lacking functional p53 and HIF-1α. Also, in normal fibroblasts and retinal cells, hypoxia inhibited the mTOR pathway and suppressed senescence caused by etoposide without affecting DNA damage response, p53/p21 induction and cell cycle arrest. Also hypoxia suppressed geroconversion in cells treated with nutlin-3a, a nongenotoxic inducer of p53, in cell lines susceptible to nutlin-3a-induced senescence (MEL-10, A172, and NKE). Thus, in normal and cancer cell lines, hypoxia suppresses geroconversion caused by diverse stimuli. Physiological and clinical implications of the present findings are discussed.     

HBx triggers either cellular senescence or cell proliferation depending on cellular phenotype

Replicative senescence is a hallmark of chronic liver diseases including chronic hepatitis B virus (HBV) infection, whereas HBV‐encoded oncoproteins HBx and preS2 have been found to overcome senescence. HBx possesses a C‐terminal truncation mainly in hepatocellular carcinomas but also in noncancerous liver tissues. Here, by cell counting, BrdU incorporation, MTT proliferation assay, cell cycle analysis, SA‐βgal staining and Western blotting in primary and malignant cells, we investigated the effect of HBx C‐terminal mutants on cellular senescence. HBx C‐terminal mutants were found to trigger cellular senescence in primary MRC5 cells, and malignant liver cells Huh7, and SK‐Hep1. In contrast, these mutants promoted the proliferation of HepG2 malignant liver cells. The pro‐senescent effect of HBx relied on an increased p16^INK4a and p21^Waf1/Cip1 expression, and a decreased phosphorylation of Rb. Together, these results suggest that the two main variants of HBx present in HBV‐infected liver possess opposite effects on cellular senescence that depend on the phenotype of infected cells.     

Senescence and immortalization of human cells

Following a limited number of population doublings(PD), human diploid somatic cells enter the terminalproliferation arrest state of senescence. This is anintrinsic mechanism which involves p53- andpRB/p16^INK4-mediated pathways. The mostpopular candidate for the counting mechanism whichmeasures the age of a cell in PD is telomereshortening. Recent studies have shown that senescencecan also be induced independently of a PD levelby various factors; this premature senescence alsoappears to involve the activity of p53 and/orp16^INK4. Immortalization of cells requiresabrogation of p53 and pRB-mediated terminalproliferation arrest and/or activation of a telomeremaintenance mechanism. The central role of telomeresin human cell senescence and immortalization hasreceived much attention; however there is evidencethat senescence can occur independently of telomerelength and that genes that are not necessarily involved in telomere maintenance are involved in immortalization.     

Cdkn1a is a key mediator of rat pancreatic stellate cell senescence

Background/objectivesCompletion of pancreatic wound healing requires termination of pancreatic stellate cell (PSC) activation to prevent fibrosis. Besides induction of apoptosis and return to a quiescent phenotype, senescence of PSC followed by immune cell-mediated cytolysis represents a potential mechanism. Here, we have studied if the cell cycle inhibitor cyclin-dependent kinase inhibitor 1A (Cdkn1a, p21/Waf1), expression of which is increased in senescent rat PSC, plays a causative role in the senescence process.MethodsSenescence was induced by doxorubicin treatment. The functions of Cdkn1a were analyzed using two approaches, treatment of primary rat PSC with siRNA and tetracycline-regulated overexpression of Cdkn1a in immortalized rat cells. Expression of senescence-associated β-galactosidase (SA β-Gal) was used as a surrogate marker of senescence.ResultsThe knockdown of Cdkn1a significantly attenuated the growth-inhibitory effect of doxorubicin and strongly diminished the portion of SA β-Gal-positive cells. Overexpression of Cdkn1a enhanced both the antiproliferative effect of doxorubicin and induction of senescence. In primary PSC, doxorubicin treatment was associated with increased expression of interleukin-6 (IL-6) and matrix metalloproteinase (MMP)-9, while expression of the activation marker α-smooth muscle actin (α-SMA), p53, Cdk1 and Rad54 was diminished. The application of Cdkn1a siRNA specifically antagonized the effects of doxorubicin on the expression of p53, Cdk1 and Rad54 but not IL-6 and α-SMA, while MMP-9 expression and also activity were even enhanced.ConclusionsCdkn1a plays a direct role in the process of rat PSC senescence. Additional Cdkn1a-independent pathways may contribute to the partial maintenance of a gene expression profile typical of senescent PSC.     

Cell cycle regulation in H(2)O(2)-induced premature senescence of human diploid fibroblasts and regulatory control exerted by the papilloma virus E6 and E7 proteins

Many biomarkers of replicative senescence appear in stress-induced premature senescence (SIPS) of human diploid fibroblasts (HDFs). The mRNA level of key cell cycle regulators was studied in H(2)O(2)-induced premature senescence of HDFs expressing or not the papillomavirus E6 and E7 proteins, which enhanced, respectively, the proteolysis of p53 and Rb. The CdKI's p21(waf-1) and p16(Ink-4a) were found overexpressed in H(2)O(2)-induced premature senescence, while p19(Ink-4d)and p27(Kip-1) were repressed. The results obtained in E6 HDFs suggest that p21(waf-1) and p16(Ink-4a) overexpressions are p53-independent, while p27(Kip-1) and p19(Ink-4d) down-regulations are p53-dependent.E6 regulated Rb, p130, p53 and p16(Ink-4a) mRNA level in non-stressing conditions, and regulated p130, p107, p53, p19(Ink-4d), p27(Kip-1) mRNA level in SIPS. SIPS modified the E6-mediated regulatory control on p107, p16(Ink-4a), p19(Ink-4d) and p27(Kip-1) mRNA level, when compared to normal conditions.E7 regulated the mRNA level of all the genes studied, in all conditions, suggesting that the Rb family or other E7-interacting proteins might modify the expression of these genes. SIPS modified strongly the E7-mediated regulatory control on p107, p16(Ink-4a), p19(Ink-4d), p27(Kip-1), p21(Waf-1) and Rb mRNA level, when compared to normal conditions. Further work is ongoing to test whether this E7-mediated regulatory control takes place through interactions with Rb or other E7-interacting proteins.     

健康大鼠血管衰老性重塑与血管衰老相关基因的关系

目的通过研究健康大鼠血管衰老性重塑形态学变化及衰老相关基因表达,探讨血管衰老性重塑可能的分子调控机制,为临床有效干预血管衰老提供分子靶点。方法观察主动脉组织形态及内皮细胞显微结构变化,应用Western blotting分析4、10、16月和24月龄大鼠血管重塑p16INK4a和p21cip1蛋白表达变化。结果随增龄,大鼠主动脉管壁增厚,纤维化程度增高,内皮细胞形态呈现衰老改变,p16INK4a和p21cip1蛋白表达呈时间依赖性上调。结论血管衰老性重塑的分子机制之一可能与上调细胞周期蛋白p16INK4a和p21cip1的表达有关。进一步阐明其调控机制可为延缓血管衰老,防治动脉粥样硬化提供理论依据。     

Surveillance mechanism linking Bub1 loss to the p53 pathway

Bub1 is a kinase believed to function primarily in the mitotic spindle checkpoint. Mutation or aberrant Bub1 expression is associated with chromosomal instability, aneuploidy, and human cancer. We now find that targeting Bub1 by RNAi or simian virus 40 (SV40) large T antigen in normal human diploid fibroblasts results in premature senescence. Interestingly, cells undergoing replicative senescence were also low in Bub1 expression, although ectopic Bub1 expression in presenescent cells was insufficient to extend lifespan. Premature senescence caused by lower Bub1 levels depends on p53. Senescence induction was blocked by dominant negative p53 expression or depletion of p21(CIP1), a p53 target. Importantly, cells with lower Bub1 levels and inactivated p53 became highly aneuploid. Taken together, our data highlight a role for p53 in monitoring Bub1 function, which may be part of a more general spindle checkpoint surveillance mechanism. Our data support the hypothesis that Bub1 compromise triggers p53-dependent senescence, which limits the production of aneuploid and potentially cancerous cells.     

The human melanocyte: a model system to study the complexity of cellular aging and transformation in non-fibroblastic cells

The melanocyte is a neural crest-derived cell that localizes in humans to several organs including the epidermis, eye, inner ear and leptomeninges. In the skin, melanocytes synthesize and transfer melanin pigments to surrounding keratinocytes, leading to skin pigmentation and protection against solar exposure. We have investigated the process of replicative senescence and accompanying irreversible cell cycle arrest, in melanocytes in culture. As was found in other cell types, progressive telomere shortening appears to trigger replicative senescence in normal melanocytes. In addition, senescence is associated with increased binding of the cyclin-dependent kinase inhibitor (CDK-I) p16(INK4a) to CDK4, down-regulation of cyclin E protein levels (and consequent loss of cyclin E/CDK2 activity), underphosphorylation of the retinoblastoma protein RB and subsequent increased levels of E2F4-RB repressive complexes. In contrast to fibroblasts, however, the CDK-Is p21(Waf-1) and p27(Kip-1) are also down-regulated. These changes appear to be important for replicative senescence because they do not occur in melanocytes that overexpress the catalytic subunit of the enzyme telomerase (hTERT), or in melanomas, which are tumors that originate from melanocytes or melanoblasts. In contrast to unmodified melanocytes, hTERT overexpressing (telomerized) melanocytes displayed telomerase activity, stable telomere lengths and an extended replicative life span. However, telomerized melanocytes show changes in cell cycle regulatory proteins, including increased levels of cyclin E, p21(Waf-1) and p27(Kip-1). Cyclin E, p21(Waf-1) and p27(Kip-1) are also elevated in many primary melanomas, whereas p16(INK4a) is mutated or deleted in many invasive and metastatic melanomas. Thus, the molecular mechanisms leading to melanocyte senescence and transformation differ significantly from fibroblasts. This suggests that different cell types may use different strategies to halt the cell cycle in response to telomere attrition and thus prevent replicative immortality.