Publications
2002
Werner syndrome is a rare autosomal recessive disorder involving the premature appearance of features reminiscent of human aging. Werner syndrome occurs by mutation of the WRN gene, encoding a DNA helicase. WRN contributes to the induction of the p53 tumor suppressor protein by various DNA damaging agents. Here we show that UV exposure leads to extensive translocation of WRN from the nucleolus to nucleoplasmic foci in a dose-dependent manner. Ionizing radiation also induces WRN translocation, albeit milder, partially through activation of the ATM kinase. The nucleoplasmic foci to which WRN is recruited display partial colocalization with PML nuclear bodies. The translocation of WRN into nucleoplasmic foci is significantly enhanced by the protein deacetylase inhibitor, Trichostatin A. Moreover, Trichostatin A delays the re-entry of WRN into the nucleolus at late times after irradiation. WRN is acetylated in vivo, and this is markedly stimulated by the acetyltransferase p300. Importantly, p300 augments the translocation of WRN into nucleoplasmic foci. These findings support the notion that WRN plays a role in the cellular response to DNA damage and suggest that the activity of WRN is modulated by DNA damage-induced post-translational modifications of WRN and possibly WRN-interacting proteins.
The p53 tumor suppressor protein provides a major anti-cancer defense mechanism, as underscored by the fact that the p53 gene is the most frequent target for genetic alterations in human cancer. Recent work has led to the realization that p53 lies at the hub of a very complex network of signaling pathways that integrate a variety of intracellular and extracellular inputs. Part of this network consists of an array of autoregulatory feedback loops, where p53 exhibits very intricate interactions with other proteins known to play important roles in the determination of cell fate. We discuss two such loops, one involving the ?-catenin protein and the other centering on the Akt/PKB protein kinase. In both cases, the central module is the interplay between p53 and the Mdm2 protein, which inactivates p53 and targets it for rapid proteolysis. Whereas deregulated ?-catenin can lead to Mdm2 inactivation and p53 accumulation, active p53 can promote the degradation and down-regulation of ?-catenin. Similarly, Akt can block p53 activation by potentiating Mdm2, whereas activated p53 can tune down Akt in several different ways. In each case, the actual output of the loop is determined by the delicate balance between the opposing effects of its different components. Often, this balance is dictated by additional signaling processes that occur simultaneously within the same cell. Genetic alterations characteristic of cancer are capable of severely distorting this balance, thereby overriding the tumor suppressor effects of p53 in a manner that facilitates neoplastic conversion.
β-Catenin and its close homologue plakoglobin (τ-catenin) are major constituents of submembranal cell-cell adhesion sites. In addition, β-catenin is a key component in the canonical Wnt pathway. Aberrantly activated β-catenin signaling contributes to cancer progression by inducing [in complex with lymphocyte enhancer factor (LEF)/T-cell factor (TCF)] the transcription of proliferation-related genes such as cyclin DI and c-myc. Plakoglobin can also activate LEF/TCF-mediated transcription. Excessive β-catenin signaling in MEF triggers a p53-mediated antiproliferative response by inducing the expression of ARF. We have demonstrated previously that plakoglobin also exerts a tumor-suppressive effect in certain cancer cell lines. To identify genes induced by β-catenin and plakoglobin, DNA microarray analysis was carried out, and PML was among those genes of which the expression was significantly elevated by both plakoglobin and β-catenin. Activation of the PML promoter by β-catenin and plakoglobin was LEF/TCF-independent. We found that PML forms a complex with β-catenin in cells, and the two proteins colocalize in the nucleus. In addition, PML, p300, and β-catenin cooperated in transactivation of a subset of β-catenin-responsive genes including ARF and Siamois but not cyclin D1. Retroviral expression of β-catenin, plakoglobin, or PML suppressed the tumorigenicity of p53-negative human renal carcinoma cells, thus pointing to a novel antioncogenic response triggered by catenins that is mediated by the induction of PML.
Phosphorylation of Mdm2, in response to DNA damage, resulted in prevention of p53 degradation in the cytoplasm as well as reduction of its binding with monoclonal antibody (mAb) 2A10. Using a 15-mer phage-peptide library, we identified two 2A10-epitopes on human Mdm2 (hdm2): at positions 255-266 (LDSEDYSLSEEG) and 389-400 (QESDDYSQPSTS). Synthetic peptides corresponding to the above sites, inhibit the binding of mAb2A10 to Mdm2 with high (4.5×10-9M) and moderate affinity (1.1×10-7M), respectively. Phospho-derivatives of these peptides, and of single human Mdm2 mutations S260D or S395D resulted in a considerable reduction in their binding with mAb2A10. These results provide a molecular explanation for the observation that reactivity of Mdm2 with mAb2A10 is inhibited by phosphorylation.
The p53 tumor suppressor is inhibited and destabilized by Mdm2. However, under stress conditions, this downregulation is relieved, allowing the accumulation of biologically active p53. Recently we showed that c-Abl is important for p53 activation under stress conditions. In response to DNA damage, c-Abl protects p53 by neutralizing the inhibitory effects of Mdm2. In this study we ask whether this neutralization involves a direct interplay between c-Abl and Mdm2, and what is the contribution of the c-Abl kinase activity? We demonstrate that the kinase activity of c-Abl is required for maintaining the basal levels of p53 expression and for achieving maximal accumulation of p53 in response to DNA damage. Importantly, c-Abl binds and phosphorylates Mdm2 in vivo and in vitro. We characterize Hdm2 (human Mdm2) phosphorylation at Tyr394. Substitution of Tyr394 by Phe394 enhances the ability of Mdm2 to promote p53 degradation and to inhibit its transcriptional and apoptotic activities. Our results suggest that phosphorylation of Mdm2 by c-Abl impairs the inhibition of p53 by Mdm2, hence defining a novel mechanism by which c-Abl activates p53.
The p53 tumor suppressor gene is the most frequent target for genetic alterations in human cancers, whereas the recently discovered homologues p73 and p63 are rarely mutated. We and others have previously reported that human tumor-derived p53 mutants can engage in a physical association with different isoforms of p73, inhibiting their transcriptional activity. Here, we report that human tumor-derived p53 mutants can associate in vitro and in vivo with p63 through their respective core domains. We show that the interaction with mutant p53 impairs in vitro and in vivo sequence-specific DNA binding of p63 and consequently affects its transcriptional activity. We also report that in cells carrying endogenous mutant p53, such as T47D cells, p63 is unable to recruit some of its target gene promoters. Unlike wild-type p53, the binding to specific p53 mutants markedly counteracts p63-induced growth inhibition. This effect is, at least partially, mediated by the core domain of mutant p53. Thus, inactivation of p53 family members may contribute to the biological properties of specific p53 mutants in promoting tumorigenesis and in conferring selective survival advantage to cancer cells.
Nitric oxide (NO) is an important bioactive molecule involved in a variety of physiological and pathological processes. At the same time, NO is also an inducer of stress signaling, owing to its ability to damage proteins and DNA. NO was reported to be a potent activator of the p53 tumor suppressor protein. However, the mechanisms underlying p53 activation by NO remain to be elucidated. We report here that NO induces the accumulation of transcriptionally active p53 in a variety of cell types and that NO signaling to p53 does not require ataxia telangiectasia-mutated (ATM), poly(ADP-ribose) polymerase 1, or the ARF tumor suppressor protein. In mouse embryonic fibroblasts, NO elicits a down-regulation of Mdm2 protein levels that precedes the rise in p53. NO-induced down-regulation of Mdm2 protein but not its mRNA also occurs in several p53-deficient cell types and is thus p53-independent. The drop in endogenous Mdm2 levels following NO treatment is accompanied by a corresponding reduction in the rate of p53 ubiquitination. Thus, the down-regulation of Mdm2 by NO is likely to contribute to the activation of p53.
The Mdm2 proto-oncogene is amplified and over-expressed in a variety of tumors. One of the major functions of Mdm2 described to date is its ability to modulate the levels and activity of the tumor suppressor protein p53. Mdm2 binds to the N-terminus of p53 and, through its action as an E3 ubiquitin ligase, targets p53 for rapid proteasomal degradation. Mdm2 can also bind to other cellular proteins such as hNumb, E2F1, Rb and Akt; however, the biological significance of these interactions is less clear. To gain insight into the function of Mdm2 in vivo, we have generated a transgenic Drosophila strain bearing the mouse Mdm2 gene. Ectopic expression of Mdm2, using the UAS/GAL4 system, causes eye and wing phenotypes in the fly. Analysis of wing imaginal discs from third instar larvae showed that expression of Mdm2 induces apoptosis. Crosses did not reveal genetic interactions between Mdm2 and the Drosophila homolog of E2F, Numb and Akt. These transgenic flies may provide a unique experimental model for exploring the molecular interactions of Mdm2 in a developmental context.
Cells within an organism are occasionally exposed to either intracellular or environmental stress. Such stress often has genotoxic potential that enhances the probability of cancer. Two gene families, the p53 family (p53, p63 and p73) and the Mdm2 family (Mdm2 and MdmX), serve as major integrators of the signals generated by genotoxic and oncogenic stress. Their co-ordinated modulation ensures an optimal response to stress and decreases the likelihood of cancer. Work over the past year has provided better understanding of the p53-Mdm2 module that lies in the heart of this regulatory network, and of the intricate interplay between the various members of the network.
The p53 tumor suppressor protein and the Akt/PKB kinase play important roles in the transduction of pro-apoptotic and anti-apoptotic signals, respectively. We provide evidence that conflicting signals transduced by Akt and p53 are integrated via negative feedback between the two pathways. On the one hand, the combination of ionizing radiation and survival factor deprivation, which leads to rapid apoptosis of IL-3 dependent DA-1 cells, entails a caspase- and p53-dependent destruction of Akt. This destruction of Akt is not a secondary consequence of apoptosis, since it is not seen when the same cells are triggered to undergo apoptosis under different conditions. On the other hand upon serum stimulation, when Akt becomes active and enhances cell survival, phosphorylation occurs at an Akt consensus site (serine 166) within the Mdm2 protein, a key regulator of p53 function. Taken together, our findings suggest that depending on the balance of signals, p53-dependent downregulation of Akt may promote an irreversible commitment to apoptotic cell death, whereas effective recruitment of Akt by appropriate survival signals may lead to activation of Mdm2, inactivation of p53, and eventually inhibition of p53-dependent apoptosis.
The tumor suppressor protein p53 is ubiquitously expressed as a major isoform of 53 kD, but several forms of lower molecular weight have been observed. Here, we describe a new isoform, ΔN-p53, produced by internal initiation of translation at codon 40 and lacking the N-terminal first transactivation domain. This isoform has impaired transcriptional activation capacity, and does not complex with the p53 regulatory protein Mdm2. Furthermore, ΔN-p53 oligomerizes with full-length p53 (FL-p53) and negatively regulates its transcriptional and growth-suppressive activities. Consistent with the lack of Mdm2 binding, ΔN-p53 does not accumulate in response to DNA-damage, suggesting that this isoform is not involved in the response to genotoxic stress. However, in serum-starved cells expressing wild-type p53, ΔN-p53 becomes the predominant p53 form during the synchronous progression into S phase after serum stimulation. These results suggest that ΔN-p53 may play a role as a transient, negative regulator of p53 during cell cycle progression.