CHIP-dependent p53 regulation occurs specifically during cellular senescence

p53 regulates several biological processes, including senescence. Its protein stability is regulated by ubiquitination and proteasomal degradation, mainly mediated by Mdm2. However, other E3 ligases have been identified, such as the chaperone-associated ligase CHIP, although their precise function regarding p53 degradation remains elusive. Interestingly, CHIP deficiency has been recently shown to result in accelerated aging in mice, although the molecular basis of this phenotype was not completely understood. In this study, we explore the role of CHIP in regulating p53 in senescence. We demonstrate that in senescent human fibroblasts, CHIP is up-regulated concomitant with a significant down-regulation of p53. Moreover, CHIP partially translocates to the nucleus and acquires higher ubiquitination levels in senescent cells. Notably, CHIP overexpression in young cells, to levels similar to those recorded during senescence, leads to p53 degradation to below its basal levels. In addition, whereas CHIP silencing has no effect on p53 stability in young cells, a considerable p53 accumulation occurs in their senescent counterparts. Finally, we have observed an attenuation of the CHIP-associated molecular folding-refolding machinery during senescence, and supportively, inhibition of Hsp90 activity leads to rapid p53 degradation only in senescent cells. Taking these results together, we conclude that CHIP-dependent p53 regulation occurs specifically during senescence.     

Cooperation between p53 and p130(Rb2) in induction of cellular senescence

To determine pathways cooperating with p53 in cellular senescence when the retinoblastoma protein (pRb)/p16INK4a pathway is defunct, we stably transfected the p16INK4a-negative C6 rat glioma cell line with a temperature-sensitive mutant p53. Activation of p53(Val-135) induces a switch in pocket protein expression from pRb and p107 to p130(Rb2) and stalls the cells in late G1, early S-phase at high levels of cyclin E. Maintenance of the arrest depends on the functions of p130(Rb2) repressing cyclin A. Inactivation of p53 in senescent cultures restores the pocket proteins to initial levels and initiates progression into S-phase, but the cells fail to resume proliferation, likely due to DNA damage becoming apparent in the arrest and activating apoptosis subsequent to the release from p53-dependent growth suppression. The data indicate that p53 can cooperate selectively with p130(Rb2) to induce cellular senescence, a pathway that may be relevant when the pRb/p16INK4a pathway is defunct.     

Human SIR2 deacetylates p53 and antagonizes PML/p53-induced cellular senescence

The yeast Sir2 protein mediates chromatin silencing through an intrinsic NAD-dependent histone deacetylase activity. Sir2 is a conserved protein and was recently shown to regulate lifespan extension both in budding yeast and worms. Here, we show that SIRT1, the human Sir2 homolog, is recruited to the promyelocytic leukemia protein (PML) nuclear bodies of mammalian cells upon overexpression of either PML or oncogenic Ras (Ha-rasV12). SIRT1 binds and deacetylates p53, a component of PML nuclear bodies, and it can repress p53-mediated transactivation. Moreover, we show that SIRT1 and p53 co-localize in nuclear bodies upon PML upregulation. When overexpressed in primary mouse embryo fibroblasts (MEFs), SIRT1 antagonizes PML-induced acetylation of p53 and rescues PML-mediated premature cellular senescence. Taken together, our data establish the SIRT1 deacetylase as a novel negative regulator of p53 function capable of modulating cellular senescence.     

Regulation of cellular senescence by p53.

Many normal cells respond to potentially oncogenic stimuli by undergoing cellular senescence, a state of irreversibly arrested proliferation and altered differentiated function. Cellular senescence very likely evolved to suppress tumorigenesis. In support of this idea, it is regulated by several tumor suppressor genes. At the heart of this regulation is p53. p53 is essential for the senescence response to short telomeres, DNA damage, oncogenes and supraphysiological mitogenic signals, and overexpression of certain tumor suppressor genes. Despite the well-documented central role for p53 in the senescence response, many questions remain regarding how p53 senses senescence-inducing stimuli and how it elicits the senescent phenotype.     

Oncogenic ras and p53 cooperate to induce cellular senescence

Oncogenic activation of the mitogen-activated protein (MAP) kinase cascade in murine fibroblasts initiates a senescence-like cell cycle arrest that depends on the ARF/p53 tumor suppressor pathway. To investigate whether p53 is sufficient to induce senescence, we introduced a conditional murine p53 allele (p53(val135)) into p53-null mouse embryonic fibroblasts and examined cell proliferation and senescence in cells expressing p53, oncogenic Ras, or both gene products. Conditional p53 activation efficiently induced a reversible cell cycle arrest but was unable to induce features of senescence. In contrast, coexpression of oncogenic ras or activated mek1 with p53 enhanced both p53 levels and activity relative to that observed for p53 alone and produced an irreversible cell cycle arrest that displayed features of cellular senescence. p19(ARF) was required for this effect, since p53(-/-) ARF(-/-) double-null cells were unable to undergo senescence following coexpression of oncogenic Ras and p53. Although the levels of exogenous p53 achieved in ARF-null cells were relatively low, the stabilizing effects of p19(ARF) on p53 could not explain the cooperation between oncogenic Ras and p53 in promoting senescence. Hence, enforced p53 expression without oncogenic ras in p53(-/-) mdm2(-/-) double-null cells produced extremely high p53 levels but did not induce senescence. Taken together, our results indicate that oncogenic activation of the MAP kinase pathway in murine fibroblasts converts p53 into a senescence inducer through both quantitative and qualitative mechanisms.     

p53 deacetylation by SIRT1 decreases during protein kinase CKII downregulation-mediated cellular senescence

Cellular senescence is thought to be an important tumor suppression process in vivo. We have previously shown that p53 activation is necessary for CKII inhibition-mediated cellular senescence. Here, CKII inhibition induced acetylation of p53 at K382 in HCT116 and HEK293 cells. This acetylation event was suppressed by SIRT1 activation. CKIIα and CKIIβ were co-immunoprecipitated with SIRT1 in a p53-independent manner. Maltose binding protein pull-down and yeast two-hybrid indicated that SIRT1 bound to CKIIβ, but not to CKIIα. CKII inhibition reduced SIRT1 activity in cells. CKII phosphorylated and activated human SIRT1 in vitro. Finally, SIRT1 overexpression antagonized CKII inhibition-mediated cellular senescence. These results reveal that CKII downregulation induces p53 stabilization by negatively regulating SIRT1 deacetylase activity during senescence.     

Nucleostemin delays cellular senescence and negatively regulates TRF1 protein stability

Nucleostemin (NS) encodes a nucleolar GTP-binding protein highly enriched in the stem cells and cancer cells. To determine its biological activity in vivo, we generated NS loss- and gain-of-function mouse models. The embryogenesis of homozygous NS-null (NS^−/−) mice was aborted before the blastula stage. Although the growth and fertility of heterozygous NS-null (NS^+/−) mice appeared normal, NS^+/− mouse embryonic fibroblasts (MEFs) had fewer NS proteins, a lower population growth rate, and higher percentages of senescent cells from passage 5 (P5) to P7 than their wild-type littermates. Conversely, transgenic overexpression of NS could rescue the NS^−/− embryo in a dose-dependent manner, increase the population growth rate, and reduce the senescent percentage of MEFs. Cell cycle analyses revealed increased pre-G₁ percentages in the late-passage NS^+/− MEF cultures compared to the wild-type cultures. We demonstrated that NS could interact with telomeric repeat-binding factor 1 (TRF1) and enhance the degradation but not the ubiquitination of the TRF1 protein, which negatively regulates telomere length and is essential for early embryogenesis. This work demonstrates the roles of NS in establishing early embryogenesis and delaying cellular senescence of MEFs and reveals a mechanism of a NS-regulated degradation of TRF1.     

Spatio-temporal association between mTOR and autophagy during cellular senescence

Evidence for a connection between lysosomes and mTOR is emerging. Seminal work from the Sabatini laboratory has shown that mTOR can be recruited to the lysosomal surface in response to amino acids, in a Rag GTPase-dependent manner, to become activated by Rheb. However the biological significance of this is not fully understood. Recent work from our laboratory has shown that lysosomes spatially link mTOR and autophagy forming a cytoplasmic compartment in close proximity to the Golgi apparatus (GA) during oncogenic Ras-induced senescence. The TOR-autophagy spatial coupling compartment (TASCC) is enriched for autolysosomes, but largely excludes autophagosomes. Our data suggest that mTOR, which is a positive regulator of protein synthesis, is recruited, in part, by the amino acid-rich environment surrounding the autolysosomes. This then facilitates protein synthesis at the nearby rER-GA system, reinforcing lysosome and autophagy biogenesis. Proper TASCC formation contributes to the production of secretory proteins, which also utilizes the rER-GA system. Since mTOR inhibits autophagy during the initial stages of autophagosome formation, TASCC formation is likely to facilitate autophagy by sequestering mTOR, suggesting that the TASCC is a self-enhancing structure.     

Spatio-temporal association between mTOR and autophagy during cellular senescence

Evidence for a connection between lysosomes and mTOR is emerging. Seminal work from the Sabatini laboratory has shown that mTOR can be recruited to the lysosomal surface in response to amino acids, in a Rag GTPase-dependent manner, to become activated by Rheb. However the biological significance of this is not fully understood. Recent work from our laboratory has shown that lysosomes spatially link mTOR and autophagy forming a cytoplasmic compartment in close proximity to the Golgi apparatus (GA) during oncogenic Ras-induced senescence. The TOR-autophagy spatial coupling compartment (TASCC) is enriched for autolysosomes, but largely excludes autophagosomes. Our data suggest that mTOR, which is a positive regulator of protein synthesis, is recruited, in part, by the amino acid-rich environment surrounding the autolysosomes. This then facilitates protein synthesis at the nearby rER-GA system, reinforcing lysosome and autophagy biogenesis. Proper TASCC formation contributes to the production of secretory proteins, which also utilizes the rER-GA system. Since mTOR inhibits autophagy during the initial stages of autophagosome formation, TASCC formation is likely to facilitate autophagy by sequestering mTOR, suggesting that the TASCC is a self-enhancing structure.     

Mitogenic signalling and the p16INK4a-Rb pathway cooperate to enforce irreversible cellular senescence

The p16(INK4a) cyclin-dependent kinase inhibitor has a key role in establishing stable G1 cell-cycle arrest through activating the retinoblastoma (Rb) tumour suppressor protein pRb in cellular senescence. Here, we show that the p16(INK4a) /Rb-pathway also cooperates with mitogenic signals to induce elevated intracellular levels of reactive oxygen species (ROS), thereby activating protein kinase Cdelta (PKCdelta) in human senescent cells. Importantly, once activated by ROS, PKCdelta promotes further generation of ROS, thus establishing a positive feedback loop to sustain ROS-PKCdelta signalling. Sustained activation of ROS-PKCdelta signalling irreversibly blocks cytokinesis, at least partly through reducing the level of WARTS (also known as LATS1), a mitotic exit network (MEN) kinase required for cytokinesis, in human senescent cells. This irreversible cytokinetic block is likely to act as a second barrier to cellular immortalization ensuring stable cell-cycle arrest in human senescent cells. These results uncover an unexpected role for the p16(INK4a)-Rb pathway and provide a new insight into how senescent cell-cycle arrest is enforced in human cells.     

Telomere dysfunction suppresses spontaneous tumorigenesis in vivo by initiating p53-dependent cellular senescence

Dysfunctional telomeres induce p53-dependent cellular senescence and apoptosis, but it is not known which function is more important for tumour suppression in vivo. We used the p53 ( R172P ) knock-in mouse, which is unable to induce apoptosis but retains intact cell-cycle arrest and cellular senescence pathways, to show that spontaneous tumorigenesis is potently repressed in Terc -/- p53 ( R172P ) mice. Tumour suppression is accompanied by global induction of p53, p21 and the senescence marker senescence-associated-beta-galactosidase. By contrast, cellular senescence was unable to suppress chemically induced skin carcinomas. These results indicate that suppression of spontaneous tumorigenesis by dysfunctional telomeres requires the activation of the p53-dependent cellular senescence pathway.     

MageA2 restrains cellular senescence by targeting the function of PMLIV/p53 axis at the PML-NBs

MAGE-A genes are a subfamily of the melanoma antigen genes (MAGEs), whose expression is restricted to tumor cells of different origin and normal tissues of the human germline. Although the specific function of individual MAGE-A proteins is being currently explored, compelling evidence suggest their involvement in the regulation of different pathways during tumor progression. We have previously reported that MageA2 binds histone deacetylase (HDAC)3 and represses p53-dependent apoptosis in response to chemotherapeutic drugs. The promyelocytic leukemia (PML) tumor suppressor is a regulator of p53 acetylation and function in cellular senescence. Here, we demonstrate that MageA2 interferes with p53 acetylation at PML-nuclear bodies (NBs) and with PMLIV-dependent activation of p53. Moreover, a fraction of MageA2 colocalizes with PML-NBs through direct association with PML, and decreases PMLIV sumoylation through an HDAC-dependent mechanism. This reduction in PML post-translational modification promotes defects in PML-NBs formation. Remarkably, we show that in human fibroblasts expressing RasV12 oncogene, MageA2 expression decreases cellular senescence and increases proliferation. These results correlate with a reduction in NBs number and an impaired p53 response. All these data suggest that MageA2, in addition to its anti-apoptotic effect, could have a novel role in the early progression to malignancy by interfering with PML/p53 function, thereby blocking the senescence program, a critical barrier against cell transformation.     

Implication of p53-dependent cellular senescence related gene, TARSH in tumor suppression

A novel target of NESH-SH3 (TARSH) was identified as a cellular senescence related gene in mouse embryonic fibroblasts (MEFs) replicative senescence, the expression of which has been suppressed in primary clinical lung cancer specimens. However, the molecular mechanism underlying the regulation of TARSH involved in pulmonary tumorigenesis remains unclear. Here we demonstrate that the reduction of TARSH gene expression by short hairpin RNA (shRNA) system robustly inhibited the MEFs proliferation with increase in senescence-associated β-galactosidase (SA-β-gal) activity. Using p53^−/− MEFs, we further suggest that this growth arrest by loss of TARSH is evoked by p53-dependent p21^Cip1 accumulation. Moreover, we also reveal that TARSH reduction induces multicentrosome in MEFs, which is linked in chromosome instability and tumor development. These results suggest that TARSH plays an important role in proliferation of replicative senescence and may serve as a trigger of tumor development.     

A role for both RB and p53 in the regulation of human cellular senescence.

We present evidence for the possible involvement of both the RB and p53 proteins in the regulation of cellular senescence. Human fibroblasts immortalized with an inducible SV40 T-antigen become senescent following the de-induction of T-antigen. Plasmids expressing an alternative source of intact T-antigen restore proliferation but T-antigen deletion mutants lacking either the RB or p53 binding domains are unable to do so. Similarly, combinations of adenovirus E1A + E1B or human papillomavirus E6 + E7 genes are able to replace T-antigen functions and permit cell proliferation, whereas the individual genes do not. These results are discussed in terms of a two-stage model for the escape from in vitro cellular senescence.     

Weak p53 permits senescence during cell cycle arrest

Cell cycle arrest coupled with hyper-active mTOR leads to cellular senescence. While arresting cell cycle, high levels of p53 can inhibit mTOR (in some cell lines), thus causing reversible quiescence instead of senescence. Nutlin-3a-induced p53 inhibited mTOR and thus caused quiescence in WI-38 cells. In contrast, while arresting cell cycle, the DNA-damaging drug doxorubicin (DOX) did not inhibit mTOR and caused senescence. Super-induction of p53 by either nutlin-3a or high concentrations of DOX (high-DOX) prevented low-DOX-induced senescence, converting it into quiescence. This explains why in order to cause senescence, DNA damaging drugs must be used at low concentrations, which arrest cell cycle but do not induce p53 at levels sufficient to suppress mTOR. Noteworthy, very prolonged treatment with nutlin-3a also caused senescence preventable by rapamycin. In RPE cells, low concentrations of nutlin-3a caused a semi-senescent morphology. Higher concentrations of nutlin-3a inhibited mTOR and caused quiescent morphology. We conclude that low p53 levels during prolonged cell cycle arrest tend to cause senescence, whereas high levels of p53 tend to cause either quiescence or cell death.     

MKK7 couples stress signalling to G2/M cell-cycle progression and cellular senescence

During the development of multicellular organisms, concerted actions of molecular signalling networks determine whether cells undergo proliferation, differentiation, death or ageing. Here we show that genetic inactivation of the stress signalling kinase, MKK7, a direct activator of JNKs in mice, results in embryonic lethality and impaired proliferation of hepatocytes. Beginning at passage 4-5, mkk7(-/-) mouse embryonic fibroblasts (MEFs) display impaired proliferation, premature senescence and G2/M cell cycle arrest. Similarly, loss of c-Jun or expression of a c-JunAA mutant in which the JNK phosphorylation sites were replaced with alanine results in a G2/M cell-cycle block. The G2/M cell-cycle kinase CDC2 was identified as a target for the MKK7-JNK-c-Jun pathway. These data show that the MKK7-JNK-c-Jun signalling pathway couples developmental and environmental cues to CDC2 expression, G2/M cell cycle progression and cellular senescence in fibroblasts.     

Expression profiles of p53 and p66shc during oxidative stress-induced senescence in fetal bovine fibroblasts

Somatic cells undergo a permanent cell cycle arrest, called cellular senescence, after a limited number of cell divisions in vitro. Both the tumor suppressor protein p53 and the stress-response protein p66(shc) are suggested to regulate the molecular events associated with senescence. This study was undertaken to investigate the effect of different oxygen tensions and oxidative stress on cell longevity and to establish the role of p53 and p66(shc) in cells undergoing senescence. As a model of cellular senescence, primary fetal bovine fibroblasts were cultured in either 20% O(2) or 5% O(2) atmospheres until senescence was reached. Fibroblasts cultured under 20% O(2) tension underwent senescence after 30 population doublings (PD), whereas fibroblasts cultured under 5% O(2) tension did not exhibit signs of senescence. Oxidative stress, as measured by protein carbonyl content, was significantly elevated in senescent cells compared to their younger counterparts and to fibroblasts cultured under 5% O(2) at the same PD. p53 mRNA gradually decreased in 20% O(2) cultured fibroblasts until senescence was reached, whereas p53 protein levels were significantly increased as well as p53 phosphorylation on serine 20, suggesting that p53 might be stabilized by posttranslational modifications during senescence. Senescence was also associated with high levels of p66(shc) mRNA and protein levels, while the levels remained low and stable in dividing fibroblasts under 5% O(2) atmosphere. Taken together, our results show an effect of oxidative stress on the replicative life span of fetal bovine fibroblasts as well as an involvement of p53, serine 20-p53 phosphorylation and p66(shc) in senescence.