Stabilization of the MDM2 oncoprotein by mutant p53

MDM2 is a short-lived protein that regulates p53 degradation. We report here that transient coexpression of MDM2 and several p53 hotspot mutants resulted in stabilization and increased expression of MDM2. Ectopic expression of the mutant p53(175H) allele by recombinant adenovirus infection or stable transfection also stabilized endogenous MDM2 in p53-null cells. A panel of human tumor cell lines expressing different endogenous mutant p53 alleles also contained stabilized nuclear MDM2 at elevated levels when compared with p53-null cells. MDM2 was present in complexes with mutant p53 in tumor cells, and stabilization of MDM2 required direct binding to mutant p53. These results reveal a novel property of mutant p53 and a unique feature of tumors with p53 missense mutations. Accumulation of stable MDM2 may contribute to tumorigenesis through its p53-independent transforming functions.     

RYBP stabilizes p53 by modulating MDM2

The mouse double minute 2 (MDM2)–p53 interaction regulates the activity of p53 and is a potential target for human cancer therapy. Here, we report that RYBP (RING1‐ and YY1‐binding protein), a member of the polycomb group (PcG), interacts with MDM2 and decreases MDM2‐mediated p53 ubiquitination, leading to stabilization of p53 and an increase in p53 activity. RYBP induces cell‐cycle arrest and is involved in the p53 response to DNA damage. Expression of RYBP is decreased in human cancer tissues compared with adjacent normal tissues. These results show that RYBP is a new regulator of the MDM2–p53 loop and that it has tumour suppressor activity.     

Contribution of two independent MDM2-binding domains in p14(ARF) to p53 stabilization

The MDM2 protein targets the p53 tumor suppressor for ubiquitin-dependent degradation [1], and can function both as an E3 ubiquitin ligase [2] and as a regulator of the subcellular localization of p53 [3]. Oncogene activation stabilizes p53 through expression of the ARF protein (p14(ARF) in humans, p19(ARF) in the mouse) [4], and loss of ARF allows tumor development without loss of wild-type p53 [5] [6]. ARF binds directly to MDM2, and prevents MDM2 from targeting p53 for degradation [6] [7] [8] [9] by inhibiting the E3 ligase activity of MDM2 [2] and preventing nuclear export of MDM2 and p53 [10] [11]. Interaction between ARF and MDM2 results in the localization of both proteins to the nucleolus [12] [13] [14] through nucleolar localization signals (NoLS) in ARF and MDM2 [11] [12] [13] [14]. Here, we report a new NoLS within the highly conserved amino-terminal 22 amino acids of p14(ARF), a region that we found could interact with MDM2, relocalize MDM2 to the nucleolus and inhibit the ability of MDM2 to degrade p53. In contrast, the carboxy-terminal fragment of p14(ARF), which contains the previously described NoLS [11], did not drive nucleolar localization of MDM2, although this region could bind MDM2 and weakly inhibit its ability to degrade p53. Our results support the importance of nucleolar sequestration for the efficient inactivation of MDM2. The inhibition of MDM2 by a small peptide from the amino terminus of p14(ARF) might be exploited to restore p53 function in tumors.     

CREB represses p53-dependent transactivation of MDM2 through the complex formation with p53 and contributes to p53-mediated apoptosis in response to glucose deprivation

Recently, we have described that CREB (cAMP-responsive element-binding protein) has the ability to transactivate tumor suppressor p53 gene in response to glucose deprivation. In this study, we have found that CREB forms a complex with p53 and represses p53-mediated transactivation of MDM2 but not of p21^WAF1. Immunoprecipitation analysis revealed that CREB interacts with p53 in response to glucose deprivation. Forced expression of CREB significantly attenuated the up-regulation of the endogenous MDM2 in response to p53. By contrast, the mutant form of CREB lacking DNA-binding domain (CREBΔ) had an undetectable effect on the expression level of the endogenous MDM2. During the glucose deprivation-mediated apoptosis, there existed an inverse relationship between the expression levels of MDM2 and p53/CREB. Additionally, p53/CREB complex was dissociated from MDM2 promoter in response to glucose deprivation. Collectively, our present results suggest that CREB preferentially down-regulates MDM2 and thereby contributing to p53-mediated apoptosis in response to glucose deprivation.     

Inhibition of stress-inducible kinase pathways by tumorigenic mutant p53

More than 50% of human cancers contain p53 gene mutations and as a result accumulate altered forms of the full-length p53 protein. Although certain tumor types expressing mutant p53 protein have a poor prognostic process, the precise role of mutant p53 protein in highly malignant tumor cells is not well defined. Some p53 mutants, but not wild-type p53, are shown here to interact with Daxx, a Fas-binding protein that activates stress-inducible kinase pathways. Interaction of Daxx with p53 is highly dependent upon the specific mutation of p53. Tumorigenic mutants of p53 bind to Daxx and inhibit Daxx-dependent activation of the apoptosis signal-regulating kinase 1 stress-inducible kinases and Jun NH(2)-terminal kinase. Mutant p53 forms complexes with Daxx in cells, and consequently, mutant p53 is able to rescue cells from Daxx-dependent inhibition of proliferation. Thus, the accumulation of mutant p53 in tumor cells may contribute to tumorigenesis by inhibiting stress-inducible kinase pathways.     

DNAJB1 stabilizes MDM2 and contributes to cancer cell proliferation in a p53-dependent manner

Both MDM2 and MDMX regulate p53, but these proteins play different roles in this process. To clarify the difference, we performed a yeast 2 hybrid (Y2H) screen using the MDM2 acidic domain as bait. DNAJB1 was found to specifically bind to MDM2, but not MDMX, in vitro and in vivo. Further investigation revealed that DNAJB1 stabilizes MDM2 at the post-translational level. The C-terminus of DNAJB1 is essential for its interaction with MDM2 and for MDM2 accumulation. MDM2 was degraded faster by a ubiquitin-mediated pathway when DNAJB1 was depleted. DNAJB1 inhibited the MDM2-mediated ubiquitination and degradation of p53 and contributed to p53 activation in cancer cells. Depletion of DNAJB1 in cancer cells inhibited activity of the p53 pathway, enhanced the activity of the Rb/E2F pathway, and promoted cancer cell growth in vitro and in vivo. This function was p53 dependent, and either human papillomavirus (HPV) E6 protein or siRNA against p53 was able to block the contribution caused by DNAJB1 depletion. In this study, we discovered a new MDM2 interacting protein, DNAJB1, and provided evidence to support its p53-dependent tumor suppressor function.     

MDM2: life without p53

The MDM2 protein suppresses the ability of p53 to inhibit cellular proliferation or to induce cell death. This property underlies the oncogenic potential of MDM2, which is overexpressed in various human tumours. However, MDM2 also has p53-independent activities, which we focus on here. Similar to other oncogenes, surveillance pathways might counteract the deleterious effects of deregulated MDM2 expression. These pathways need to be inactivated for MDM2 oncogenic activity, which targets p53 but also other proteins.     

Over-expression of the human MDM2 p53 binding domain by fusion to a p53 transactivation peptide

MDM2 binds to the tumor suppressor protein p53 and regulates the level of p53 in cells. Although it is possible to prepare a small amount of the region of MDM2 that binds to p53, the expression level of this fragment of MDM2 is relatively low, limiting the studies involving this protein. Here, we describe a construct for the optimized bacterial expression and purification of the MDM2 p53 binding domain. We found that the expression level of the soluble MDM2 p53 binding domain in bacteria was increased dramatically by fusing it to its interaction partner, the p53 transactivation peptide. Attachment of the p53 transactivation peptide (residues 17-29) to the N-terminus of MDM2 resulted in a more than 200-fold increase of soluble protein expression of the p53 binding domain in bacteria. To obtain the final MDM2 p53 binding domain (residues 5-109) we inserted a tobacco etch virus protease recognition site between the P53 peptide and the MDM2 p53 binding domain. To weaken the protein/peptide interaction and facilitate the separation of the protein from the complex, we introduced a point mutation of one of the key interaction residues (F19A or W23A) in the p53 peptide. The advantages of our new construct are high yield and easy purification of the MDM2 protein.     

Downregulation of MDM2 stabilizes p53 by inhibiting p53 ubiquitination in response to specific alkylating agents

p53 is stabilized in response to DNA damaging stress. This stabilization is thought to result from phosphorylation in the N-terminus of p53, which inhibits p53:MDM2 binding, and prevents MDM2 from promoting p53 ubiquitination. In this report, the DNA alkylating agents mitomycin C (MMC) and methylmethane sulfonate (MMS), as well as UV radiation, stabilized p53 in a manner independent of phosphorylation in p53 N-terminus. This stabilization coincided with decreased levels of MDM2 mRNA and protein, and a corresponding decrease in p53 ubiquitination. Importantly, MDM2 overexpression inhibited the stabilization of p53 and decrease in ubiquitination following MMC, MMS, and UV treatment. This indicates that downregulation of MDM2 contributes to the stabilization of p53 in response to these agents.     

MDM2 binding induces a conformational change in p53 that is opposed by heat-shock protein 90 and precedes p53 proteasomal degradation

p53 protein conformation is an important determinant of its localization and activity. Changes in p53 conformation can be monitored by reactivity with wild-type conformation-specific (pAb-1620) or mutant conformation-specific (pAb-240) p53 antibodies. Wild-type p53 accumulated in a mutant (pAb-240 reactive) form when its proteasome-dependent degradation was blocked during recovery from stress treatment and in cells co-expressing p53 and MDM2. This suggests that conformational change precedes wild-type p53 degradation by the proteasome. MDM2 binding to the p53 N terminus could induce a conformational change in wild-type p53. Interestingly, this conformational change was opposed by heat-shock protein 90 and did not require the MDM2 RING-finger domain and p53 ubiquitination. Finally, ubiquitinated p53 accumulated in a pAb-240 reactive form when p53 degradation was blocked by proteasome inhibition, and a p53-ubiquitin fusion protein displayed a mutant-only conformation in MDM2-null cells. These results support a model in which MDM2 binding induces a conformational change that is opposed by heat-shock protein 90 and precedes p53 ubiquitination. The covalent attachment of ubiquitin may "lock" p53 in a mutant conformation in the absence of MDM2-binding and prior to its degradation by the proteasome.     

Structural Basis for Inhibition of the MDM2:p53 Interaction by an Optimized MDM2-Binding Peptide Selected with mRNA Display

The oncoprotein MDM2 binds to tumor suppressor protein p53 and inhibits its anticancer activity, which leads to promotion of tumor cell growth and tumor survival. Abrogation of the p53:MDM2 interaction reportedly results in reactivation of the p53 pathway and inhibition of tumor cell proliferation. We recently performed rigorous selection of MDM2-binding peptides by means of mRNA display and identified an optimal 12-mer peptide (PRFWEYWLRLME), named MDM2 Inhibitory Peptide (MIP), which shows higher affinity for MDM2 (and also its homolog, MDMX) and higher tumor cell proliferation suppression activity than known peptides. Here we determined the NMR solution structure of a MIP-MDM2 fusion protein to elucidate the structural basis of the tight binding of MIP to MDM2. A region spanning from Phe³ to Met¹¹ of MIP forms a single α-helix, which is longer than those of the other MDM2-binding peptides. MIP shares a conserved Phe³-Trp⁷-Leu¹⁰ triad, whose side chains are oriented towards and fit into the hydrophobic pockets of MDM2. Additionally, hydrophobic surface patches that surround the hydrophobic pockets of MDM2 are covered by solvent-exposed MIP residues, Trp⁴, Tyr⁶, and Met¹¹. Their hydrophobic interactions extend the interface of the two molecules and contribute to the strong binding. The potential MDM2 inhibition activity observed for MIP turned out to originate from its enlarged binding interface. The structural information obtained in the present study provides a road map for the rational design of strong inhibitors of MDM2:p53 binding.