The ARF Tumor Suppressor: Keeping Myc on a Leash

The ARF tumor suppressor protein acts in a checkpoint that guards against unscheduled cellular proliferation in response to oncogenic signaling. Deregulated expression of c-Myc induces ARF expression and apoptosis through the ARF-Mdm2-p53 axis. Our recent study reveals a new direct role for ARF in controlling c-Myc’s oncogenic activity that is independent of p53. ARF binds to and selectively impairs the transactivation ability of c-Myc while leaving its transrepression ability intact. Biologically, ARF prevents hyperproliferation and transformation caused by c-Myc and enhances c-Myc-induced apoptosis independently of p53. These new findings may be especially relevant for therapeutic strategies targeting c-Myc-induced cancers.     

TRIM28 Is an E3 Ligase for ARF-Mediated NPM1/B23 SUMOylation That Represses Centrosome Amplification

The tumor suppressor ARF enhances the SUMOylation of target proteins; however, the physiological function of ARF-mediated SUMOylation has been unclear due to the lack of a known, associated E3 SUMO ligase. Here we uncover TRIM28/KAP1 as a novel ARF-binding protein and SUMO E3 ligase for NPM1/B23. ARF and TRIM28 cooperate to SUMOylate NPM1, a nucleolar protein that regulates centrosome duplication and genomic stability. ARF-mediated SUMOylation of NPM1 was attenuated by TRIM28 depletion and enhanced by TRIM28 overexpression. Coexpression of ARF and TRIM28 promoted NPM1 centrosomal localization by enhancing its SUMOylation and suppressed centrosome amplification; these functions required the E3 ligase activity of TRIM28. Conversely, depletion of ARF or TRIM28 increased centrosome amplification. ARF also counteracted oncogenic Ras-induced centrosome amplification. Centrosome amplification is often induced by oncogenic insults, leading to genomic instability. However, the mechanisms employed by tumor suppressors to protect the genome are poorly understood. Our findings suggest a novel role for ARF in maintaining genome integrity by facilitating TRIM28-mediated SUMOylation of NPM1, thus preventing centrosome amplification.     

p53 mediates apoptosis induced by c-Myc activation in hypoxic or gamma irradiated fibroblasts

Deregulated c-Myc expression leads to a cellular state where proliferation and apoptosis are equally favored depending on the cellular microenvironment. Since the apoptotic sensitivity of many cells is influenced by the status of the p53 tumor suppressor gene, we investigated whether the induction of apoptosis by DNA damage or non-genotoxic stress are also influenced by the p53 status of cells with altered c-Myc activity. Rat-1 fibroblasts expressing a conditional c-Myc allele (c-MycER), were transfected to express an antisense RNA complimentary to p53 mRNA. Expression of antisense p53 RNA decreased p53 protein levels and delayed p53 accumulation following c-Myc activation. Under hypoxic or low serum conditions, cells expressing antisense p53 were substantially more resistant to c-Myc-induced apoptosis than were control cells. c-Myc activation also sensitized Rat-1 cells to radiation-induced apoptosis. Rat-1 cells expressing antisense p53 RNA were more resistant to apoptosis induced by the combined effects of c-Myc activation and gamma irradiation. In a similar manner, apoptosis induced by c-Myc in serum starved, hypoxic or gamma irradiated fibroblasts was also inhibited by Bcl-2. These data indicate that p53 is involved in c-Myc-mediated apoptosis under a variety of stresses which may influence tumor growth, evolution and response to therapy.     

ARF impedes NPM/B23 shuttling in an Mdm2-sensitive tumor suppressor pathway

The ARF tumor suppressor is widely regarded as an upstream activator of p53-dependent growth arrest and apoptosis. However, recent findings indicate that ARF can also regulate the cell cycle in the absence of p53. In search of p53-independent ARF targets, we isolated nucleophosmin (NPM/B23), a protein we show is required for proliferation, as a novel ARF binding protein. In response to hyperproliferative signals, ARF is upregulated, resulting in the nucleolar retention of NPM and concomitant cell cycle arrest. The Mdm2 oncogene outcompetes NPM/B23 for ARF binding, and introduction of Mdm2 reverses ARF's p53-independent properties: in vitro, NPM is released from ARF-containing protein complexes, and in vivo S phase progression ensues. ARF induction by oncogenes or replicative senescence does not alter NPM/B23 protein levels but rather prevents its nucleocytoplasmic shuttling without inhibiting rRNA processing. By actively sequestering NPM in the nucleolus, ARF utilizes an additional mechanism of tumor suppression, one that is readily antagonized by Mdm2.     

Nucleophosmin (B23) targets ARF to nucleoli and inhibits its function

The ARF tumor suppressor is a nucleolar protein that activates p53-dependent checkpoints by binding Mdm2, a p53 antagonist. Despite persuasive evidence that ARF can bind and inactivate Mdm2 in the nucleoplasm, the prevailing view is that ARF exerts its growth-inhibitory activities from within the nucleolus. We suggest ARF primarily functions outside the nucleolus and provide evidence that it is sequestered and held inactive in that compartment by a nucleolar phosphoprotein, nucleophosmin (NPM). Most cellular ARF is bound to NPM regardless of whether cells are proliferating or growth arrested, indicating that ARF-NPM association does not correlate with growth suppression. Notably, ARF binds NPM through the same domains that mediate nucleolar localization and Mdm2 binding, suggesting that NPM could control ARF localization and compete with Mdm2 for ARF association. Indeed, NPM knockdown markedly enhanced ARF-Mdm2 association and diminished ARF nucleolar localization. Those events correlated with greater ARF-mediated growth suppression and p53 activation. Conversely, NPM overexpression antagonized ARF function while increasing its nucleolar localization. These data suggest that NPM inhibits ARF's p53-dependent activity by targeting it to nucleoli and impairing ARF-Mdm2 association.     

Reactivating the ARF-p53 axis in AML cells by targeting ULF

The tumor suppressor ARF plays an essential role in the cellular response to oncogenic stress mainly through activation of p53. Nucleophosmin (NPM), a multifunctional protein, forms a stable protein complex with ARF in the nucleolus and protects ARF from the proteasome-mediated degradation. Notably, NPM is mutated in about one third of acute myeloid leukaemia (AML) patients and these mutations lead to aberrant cytoplasmic dislocation of nucleophosmin (NPM-c). Cytoplasmic NPM mutants lose their abilities to retain ARF in the nucleolus and fail to stabilize ARF. Thus, activation of the ARF-p53 axis is significantly compromised in these AML cells. We have recently identified the ubiquitin ligase of ARF (ULF) as a key factor that controls ARF turnover in human cells. Here, we found that the steady levels of both ARF and p53 are very low in human acute myeloid leukaemia OCI-AML3 cells expressing cytoplamsic dislocated nucleophosmin (NPM-c). As expected, ARF is very unstable and rapidly degraded by proteasome. Nevertheless, ULF knockdown stabilizes ARF and reactivates p53 responses in these AML cells. These results further demonstrate that ULF is a bona fide E3 ligase for ARF and also suggest that ULF is an important target for activating the ARF-p53 axis in human AML cells.Key words: ARF, ubiquitination, ULF, p53, NPM, B23, NPM-c     

B23 and ARF

B23 (nucleophosmin/NPM) is a multifunctional protein that recently has been directly implicated in the p53 network by its documented interaction with the p14(ARF)/p19(Arf) tumor suppressor, a major upstream activator of p53. Here we provide an overview of the functional interactions of B23 and ARF. We also integrate the current models into a unified picture, showing that B23 is essential for stabilizing and maintaining a basal level of ARF in the nucleolus, whereas increasing levels of ARF after oncogenic stress promotes B23 degradation and interferes with B23 nucleocytoplasmic shuttling. In this way, ARF can be regarded as a parasitic peptide on the B23 molecule, because ARF uses this chaperone for its own survival but also antagonizes normal activities of B23. Finally, the functional significance of the ARF-B23 interaction for tumor development and the prospects for novel cancer therapies are evaluated.     

Role of Pirh2 in mediating the regulation of p53 and c-Myc

Ubiquitylation is fundamental for the regulation of the stability and function of p53 and c-Myc. The E3 ligase Pirh2 has been reported to polyubiquitylate p53 and to mediate its proteasomal degradation. Here, using Pirh2 deficient mice, we report that Pirh2 is important for the in vivo regulation of p53 stability in response to DNA damage. We also demonstrate that c-Myc is a novel interacting protein for Pirh2 and that Pirh2 mediates its polyubiquitylation and proteolysis. Pirh2 mutant mice display elevated levels of c-Myc and are predisposed for plasma cell hyperplasia and tumorigenesis. Consistent with the role p53 plays in suppressing c-Myc-induced oncogenesis, its deficiency exacerbates tumorigenesis of Pirh2(-/-) mice. We also report that low expression of human PIRH2 in lung, ovarian, and breast cancers correlates with decreased patients' survival. Collectively, our data reveal the in vivo roles of Pirh2 in the regulation of p53 and c-Myc stability and support its role as a tumor suppressor.     

Reactivating the ARF-p53 axis in AML cells by targeting ULF

The tumor suppressor ARF plays an essential role in the cellular response to oncogenic stress mainly through activation of p53. Nucleophosmin (NPM), a multifunctional protein, forms a stable protein complex with ARF in the nucleolus and protects ARF from the proteasome-mediated degradation. Notably, NPM is mutated in about one third of acute myeloid leukaemia (AML) patients and these mutations lead to aberrant cytoplasmic dislocation of nucleophosmin (NPM-c). Cytoplasmic NPM mutants lose their abilities to retain ARF in the nucleolus and fail to stabilize ARF. Thus, activation of the ARF-p53 axis is significantly compromised in these AML cells. We have recently identified the ubiquitin ligase of ARF (ULF) as a key factor that controls ARF turnover in human cells. Here, we found that the steady levels of both ARF and p53 are very low in human acute myeloid leukaemia OCI-AML3 cells expressing cytoplamsic dislocated nucleophosmin (NPM-c). As expected, ARF is very unstable and rapidly degraded by proteasome. Nevertheless, ULF knockdown stabilizes ARF and reactivates p53 responses in these AML cells. These results further demonstrate that ULF is a bona fide E3 ligase for ARF and also suggest that ULF is an important target for activating the ARF-p53 axis in human AML cells.     

The ARF/p53 pathway

The ARF tumor suppressor connects pathways regulated by the retinoblastoma protein and p53. ARF inactivation reduces p53-dependent apoptosis induced by oncogenic signals. Nucleolar relocalization of Mdm2 by ARF connotes a novel mechanism for preventing p53 turnover and provides a framework for understanding how stress signals cooperate to regulate p53 function.     

Regulation of p14ARF Through Subnuclear Compartmentalization

The p53-mediated pathway cell cycle arrest and apoptosis is central to cancer and an important point of focus for therapeutics development. The p14ARF ("ARF") tumor suppressor induces the p53 pathway in response to oncogene activation or DNA damage. However, ARF is predominantly nucleolar in localization and engages in several interactions with nucleolar proteins, whereas p53 is nucleoplasmic. This raises the question as to how ARF initiates its involvement in the p53 pathway. We have found that UV irradiation of cells disrupts the interaction of ARF with two of its nucleolar binding partners, B23(NPM, nucleophosmin, NO38, numatrin) and topoisomerase I, and promotes an immediate and transient subnuclear redistribution of ARF to the nucleoplasm, where it can engage the p53 pathway (Lee et al, Cancer Research 65:9834-42; 2005). The results support a model in which the nucleolus serves as a p53 upstream sensor of cellular stress, and add to a growing body of evidence that nucleolar sequestration of ARF prevents activation of p53. The results also have therapeutic implications for therapies based on exploiting p53 and other cellular stress response pathways to suppress cancer.     

Overexpression of c-Myc alters G(1)/S arrest following ionizing radiation

Study of the mechanism(s) of genomic instability induced by the c-myc proto-oncogene has the potential to shed new light on its well-known oncogenic activity. However, an underlying mechanism(s) for this phenotype is largely unknown. In the present study, we investigated the effects of c-Myc overexpression on the DNA damage-induced G(1)/S checkpoint, in order to obtain mechanistic insights into how deregulated c-Myc destabilizes the cellular genome. The DNA damage-induced checkpoints are among the primary safeguard mechanisms for genomic stability, and alterations of cell cycle checkpoints are known to be crucial for certain types of genomic instability, such as gene amplification. The effects of c-Myc overexpression were studied in human mammary epithelial cells (HMEC) as one approach to understanding the c-Myc-induced genomic instability in the context of mammary tumorigenesis. Initially, flow-cytometric analyses were used with two c-Myc-overexpressing, nontransformed immortal lines (184A1N4 and MCF10A) to determine whether c-Myc overexpression leads to alteration of cell cycle arrest following ionizing radiation (IR). Inappropriate entry into S phase was then confirmed with a bromodeoxyuridine incorporation assay measuring de novo DNA synthesis following IR. Direct involvement of c-Myc overexpression in alteration of the G(1)/S checkpoint was then confirmed by utilizing the MycER construct, a regulatable c-Myc. A transient excess of c-Myc activity, provided by the activated MycER, was similarly able to induce the inappropriate de novo DNA synthesis following IR. Significantly, the transient expression of full-length c-Myc in normal mortal HMECs also facilitated entry into S phase and the inappropriate de novo DNA synthesis following IR. Furthermore, irradiated, c-Myc-infected, normal HMECs developed a sub-G(1) population and a >4N population of cells. The c-Myc-induced alteration of the G(1)/S checkpoint was also compared to the effects of expression of MycS (N-terminally truncated c-Myc) and p53DD (a dominant negative p53) in the HMECs. We observed inappropriate hyperphosphorylation of retinoblastoma protein and then the reappearance of cyclin A, following IR, selectively in full-length c-Myc- and p53DD-overexpressing MCF10A cells. Based on these results, we propose that c-Myc attenuates a safeguard mechanism for genomic stability; this property may contribute to c-Myc-induced genomic instability and to the potent oncogenic activity of c-Myc.     

RABL6A,a Novel RAB-Like Protein,Controls Centrosome Amplification and Chromosome Instability in Primary Fibroblasts

RABL6A (RAB-like 6 isoform A) is a novel protein that was originally identified based on its association with the Alternative Reading Frame (ARF) tumor suppressor. ARF acts through multiple p53-dependent and p53-independent pathways to prevent cancer. How RABL6A functions, to what extent it depends on ARF and p53 activity, and its importance in normal cell biology are entirely unknown. We examined the biological consequences of RABL6A silencing in primary mouse embryo fibroblasts (MEFs) that express or lack ARF, p53 or both proteins. We found that RABL6A depletion caused centrosome amplification, aneuploidy and multinucleation in MEFs regardless of ARF and p53 status. The centrosome amplification in RABL6A depleted p53−/− MEFs resulted from centrosome reduplication via Cdk2-mediated hyperphosphorylation of nucleophosmin (NPM) at threonine-199. Thus, RABL6A prevents centrosome amplification through an ARF/p53-independent mechanism that restricts NPM-T199 phosphorylation. These findings demonstrate an essential role for RABL6A in centrosome regulation and maintenance of chromosome stability in non-transformed cells, key processes that ensure genomic integrity and prevent tumorigenesis.