QUICK SEARCH:   [advanced] Author: Keyword(s):
Home     Help     Feedback     Subscriptions     Archive     Search     Table of Contents

First published online January 24, 2007
doi: 10.1242/10.1242/jcs.03362

This Article Summary Figures Only Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Marine, J.-C. W. Articles by Jochemsen, A. G. Search for Related Content PubMed PubMed Citation Articles by Marine, J.-C. W. Articles by Jochemsen, A. G.

MDMX: from bench to bedside

¹ Laboratory For Molecular Cancer Biology, Flanders Interuniversity Institute for Biotechnology (VIB), University of Ghent, B-9052 Ghent, Belgium
² Department of Developmental Neurobiology, St Jude Children's Research Hospital, Memphis, TN 38105, USA
³ Department of Molecular and Cell Biology, Leiden University Medical Center, Leiden, The Netherlands

^* Author for correspondence (e-mail: chris.marine{at}dmbr.ugent.be)

Accepted 27 November 2006

	Summary

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
The tumor suppressor protein p53 is negatively regulated by Mdm2, a ubiquitin ligase protein that targets p53 for degradation. Mdmx (also known as Mdm4) is a relative of Mdm2 that was identified on the basis of its ability to physically interact with p53. An increasing body of evidence, including recent genetic studies, suggests that Mdmx also acts as a key negative regulator of p53. Aberrant expression of MDMX could thus contribute to tumor formation. Indeed, MDMX amplification and/or overexpression occurs in several diverse tumors. Strikingly, recent work identifies MDMX as a specific chemotherapeutic target for treatment of retinoblastoma. Specific MDMX antagonists should therefore be developed as a tool to ensure activation of `dormant' p53 activity in tumors that retain wild-type p53.

Key words: p53, Mdmx, Cancer, Nutlin

	The p53-Mdm2 network

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
In response to cellular stresses such as DNA damage or oncogene activation, the tumor suppressor protein p53 becomes stabilized and modulates transcription of target genes (Vousden and Lu, 2002). These drive a variety of cellular responses to stress, including DNA repair, cell-cycle arrest, senescence and apoptosis. Key targets are the proapoptotic genes Bax, Puma and Noxa (Michalak et al., 2005), the genes encoding the cell cycle regulators p21 (el-Deiry et al., 1993) and Ptprv (Doumont et al., 2005) and the senescence-inducing gene Plasminogen activator inhibitor 1 (Kortlever et al., 2006).

In the absence of stress signals, the activity of the p53 protein is kept in check to allow normal cell proliferation and to maintain cell viability. Crucially important for this process is the product of the murine double minute gene Mdm2. Mdm2 was originally identified by virtue of its amplification in a spontaneously transformed mouse BALB/c cell line (3T3-DM) (Cahilly-Snider et al., 1987). Momand et al. later reported that Mdm2 physically associates with p53 and inhibits p53-mediated transcriptional activation (Momand et al., 1992), providing a simple explanation for its transforming potential. Amplification of MDM2 (also known as HDM2) has been observed in approximately one-third of human sarcomas that retain wild-type p53 (Oliner et al., 1992), which indicates that overexpression of MDM2 is a molecular mechanism by which cells can inactivate p53 during tumor formation.

Genetic experiments have demonstrated the importance of the Mdm2-p53 interaction. Mdm2-deficient mice die very early in development prior to implantation, whereas mice lacking both p53 and Mdm2 are viable and indistinguishable from mice lacking only p53 (Montes de Oca Luna et al., 1995; Jones et al., 1995). Similarly, Zdm2-deficient zebrafish embryos, generated by injection of antisense morpholinos, exhibit widespread apoptosis, which leads to developmental arrest. As in Mdm2-deficient mice, simultaneous inactivation of Zp53 in Zdm2-deficient zebrafish embryos rescues this developmental defect (Langheinrich et al., 2002). In addition, mice possessing a hypomorphic Mdm2 mutation exhibit defects in thymus development, metabolism, bone marrow production and intestinal cell production (Mendrysa et al., 2003). Conditional inactivation of an Mdm2^Lox allele in cardiomyocytes (Grier et al., 2006), neuronal progenitor cells (Xiong et al., 2006) and smooth muscle cells (SMCs) of the gastrointestinal (GI) tract (Boesten et al., 2006) leads to p53-dependent cell death. Finally, conditional expression of p53 in neuronal progenitor cells and post-mitotic neurons of Mdm2-null mice leads to dramatic p53 activation and cell death (Francoz et al., 2006). Mdm2 thus appears to be an essential p53 antagonist in the developing embryo and in mature differentiated cells.

Transfection studies suggest that Mdm2 inhibits p53 by multiple mechanisms. Mdm2 is a RING-finger-containing protein that acts as an E3 ligase, which is essential for ubiquitylation and subsequent degradation of p53 (Haupt et al., 1997; Kubbutat et al., 1997). Recent studies show that Mdm2 is required to maintain p53 at low levels both in proliferating and in post-mitotic cells (reviewed by Marine et al., 2006). Genetic evidence supports the notion that constitutive degradation of p53 in vivo strictly depends on Mdm2. This is particularly interesting since several other ubiquitin ligases that target p53, such as Pirh2, Cop-1 or ARF/BP1, have been discovered and shown to function in an Mdm2-independent manner (Leng et al., 2003; Dornan et al., 2004; Chen, D. et al., 2005). However, none of these proteins can sufficiently, if at all, compensate for loss of Mdm2 function in vivo.

Mdm2 binds to the transactivation domain of p53; this interaction might also interfere with the recruitment of the basal transcription machinery and/or essential co-activator(s) (Thut et al., 1997). Moreover, Mdm2 has been reported to promote conjugation of NEDD8 to p53, a modification that inhibits its transcriptional activity (Xirodimas et al., 2004). Finally, Mdm2 induces mono-ubiquitylation of histone H2B surrounding p53-response elements, which results in transcriptional repression (Minsky and Oren, 2004). Recent genetic studies are not entirely consistent with a role for Mdm2 in the regulation of p53 transcriptional activity per se, however (Marine et al., 2006). Further genetic studies, such as knockin mutations, will be necessary to resolve whether Mdm2 antagonizes p53 only through protein degradation or through repression of transcriptional activation as well.

	Mdmx, an Mdm2-related protein

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
Mdmx (also known as Mdm4) was originally isolated as a novel p53-interacting protein from a mouse cDNA expression library (Shvarts et al., 1996). The human ortholog, MDMX, was identified later (Shvarts et al., 1997). Both Mdmx and MDMX interact with p53 in cells, and Mdmx overexpression inhibits p53-activated transcription (Shvarts et al., 1996). cDNAs encoding MDMX were independently identified in a yeast two-hybrid screen for MDM2-associated proteins (Sharp et al., 1999; Tanimura et al., 1999). Indeed, the two related proteins interact in vivo. Hetero-oligomerization between Mdmx and Mdm2 appears to be much more stable than homo-oligomerization of each protein (Tanimura et al., 1999). Mdmx is thus implicated in the regulation of the p53-Mdm2 axis.

MDMX and MDM2 are structurally related proteins of 490 and 491 amino acids, respectively (Fig. 1). The greatest similarity between the two proteins is at the N-terminus, a region encompassing the p53-binding domain. The residues required for interaction with p53 are strictly conserved in MDM2 and MDMX (Shvarts et al., 1996), and the same residues in p53 are required for both MDMX-p53 and MDM2-p53 interactions (Bottger et al., 1999). Another well-conserved region common to MDMX and MDM2 is a RING-finger domain, located at the C-terminus of each protein. The integrity of the RING-finger domain is essential for MDMX-MDM2 heterodimerization (Sharp et al., 1999; Tanimura et al., 1999). Both MDM2 and MDMX also contain an additional zinc-finger domain. The function of this domain is largely unknown, but recent results suggest that an intact zinc finger, together with a central acidic domain, is essential for interaction between MDMX and casein kinase 1 alpha (CK1-) (Chen, L. et al., 2005b). The central regions of MDM2 and MDMX show no significant similarity, but both regions are rich in acidic residues.

View larger version (20K): [in this window] [in a new window]   Fig. 1. Comparison of the MDM2 and MDMX primary structures. Several functional domains are highlighted. The p53-binding domain, zinc (Zn) finger and RING finger [containing the nucleolar location signal (NoLS)] are conserved. The percentage identity shared between these domains is indicated. Although both MDM2 and MDMX contain an acidic domain, no significant conservation of amino acid sequence is found, and the acidic domain of MDMX is smaller than that of MDM2. Part of the MDMX amino acid sequence (338-407) is shown to indicate the functional domains and modification sites. Serines (S) indicated in red are validated phosphorylation sites, whereas lysines (K) indicated in blue are targets for SUMO conjugation. DVPD, caspase-3 cleavage site; NES, nuclear export signal; NLS, nuclear localization signal.

	Mdmx, another key gatekeeper of the guardian

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
Because of its similarity to Mdm2 and its ability to inhibit p53-induced transcription following overexpression, Mdmx was hypothesized to act as a negative regulator of p53 (Shvarts et al., 1996; Migliorini et al., 2002a). This view has been confirmed by loss-of-function studies in two mutant mouse lines, which concluded that, similarly to Mdm2, Mdmx acts in vivo as an essential, non-redundant, negative regulator of p53 during embryonic development. Indeed, inactivation of p53 rescues the developmental defects that otherwise occur in Mdmx-deficient mice (Parant et al., 2001; Migliorini et al., 2002b; Finch et al., 2002) (reviewed by Marine and Jochemsen, 2004).

Unfortunately, because of the early embryonic lethality associated with Mdm2-null and Mdmx-null mutations, it has been difficult to assess the physiological contributions of Mdm2 and Mdmx to the regulation of p53 levels and activity. However, conditional alleles have recently been developed that yield further insight into how and in what cell types Mdm2 and Mdmx regulate p53 (Grier et al., 2002; Steinman and Jones, 2002; Mendrysa et al., 2003; Grier et al., 2006).

To test whether Mdm2 and Mdmx are required to restrain p53 activity in a single cell type, Xiong et al. conditionally inactivated both Mdm2 and Mdmx in neuronal progenitors (Xiong et al., 2006). Meanwhile, Francoz et al. conditionally expressed p53 in neuronal progenitor cells or in post-mitotic cells of mice lacking Mdm2 and/or Mdmx (Francoz et al., 2006). Loss of Mdmx or Mdm2 leads to distinct phenotypes (see below) but, importantly, all phenotypes disappear in the absence of p53. Both Mdm2 and Mdmx are thus required to inhibit p53 activity in the same cell type, and these results confirm the notion that physiological levels of Mdm2 cannot compensate for Mdmx loss in vivo, at least in the abovementioned cell types.

Mdmx has also been conditionally inactivated in cardiomyocytes (Grier et al., 2006) and SMCs of the GI tract (Boesten et al., 2006). In contrast to loss of Mdm2, loss of Mdmx leads to only minor defects in histogenesis and tissue homeostasis. The data suggest that inhibition of p53 by Mdmx is required only in a restricted number of cell types and/or under certain physiological conditions. However, interpretation of these results is complicated. Even in cells in which Mdmx function is crucial, such as neuronal progenitor and post-mitotic cells, in contrast to Mdm2, loss of Mdmx consistently leads to only a moderate increase in p53 activity in vivo. This difference can be explained, at least in part, by the fact that p53 activates the transcription of Mdm2 (Barak et al., 1993; Wu et al., 1993) but not Mdmx. Thus, in the absence of Mdmx, p53 transcriptional activity is enhanced, leading to the stimulation of the p53-Mdm2 negative feedback loop. Indeed, Mdmx loss leads to a moderate increase in Mdm2 protein levels in vitro and an increase in Mdm2 transcription in vivo (Xiong et al., 2006; Francoz et al., 2006; Toledo et al., 2006). Note also that overexpression of an Mdm2 transgene rescues the embryonic lethality associated with Mdmx-deficiency (Steinman et al., 2005), indicating that high levels of Mdm2 compensate for Mdmx loss. Thus, increased Mdm2 levels might better compensate for Mdmx loss in specific cell types, which would represent an alternative to a more simplistic view of a tissue-specific function of Mdmx. Nevertheless, at the molecular level, the difference in the severity of the Mdm2-null and Mdmx-null phenotypes is probably as a result of the fact that loss of Mdm2 leads to dramatic accumulation of the p53 protein, whereas loss of Mdmx does not significantly increase p53 levels in vivo (see below).

The molecular details of the role of Mdmx in the control of p53 and Mdm2 stability also remain unclear. Mdmx has been reported to act as a ubiquitin ligase in vitro (Badciong and Haas, 2002), but Mdmx overexpression in cells does not lead to p53 ubiquitylation and degradation (Jackson and Berberich, 2000; Stad et al., 2000; Migliorini et al., 2002a). However, Mdmx might regulate p53 stability indirectly by stabilizing Mdm2. Indeed, transfection studies suggest that Mdmx stabilizes Mdm2, perhaps by interfering with its auto-ubiquitylation (Gu et al., 2002; Stad et al., 2001). Another report, however, suggests that Mdmx stimulates not only Mdm2-mediated ubiquitylation of p53 but also Mdm2 self-ubiquitylation (Linares et al., 2003). p53 levels stay below the limit of detection when it is conditionally expressed in progenitor and post-mitotic neuronal cells of Mdmx-null mice (Francoz et al., 2006). Similarly, p53 is not detectable in E10.5 neural progenitor cells in which Mdmx is conditionally inactivated. By contrast, clear p53 staining is observed in Mdm2-deficient cells at the same stage of development (Xiong et al., 2006). Moreover, loss of both Mdm2 and Mdmx does not lead to any further increase in p53 levels compared with loss of Mdm2 alone. This suggests that Mdmx does not participate in the regulation of p53 stability independently of Mdm2 (Francoz et al., 2006). However, whether it does so in an Mdm2-dependent manner remains unclear. The analysis of mice encoding a mutant p53 that lacks the proline-rich domain (p53^P) also enabled evaluation of Mdmx function (Toledo et al., 2006). This hypomorphic p53 mutant can fully rescue Mdmx deficiency. The consequences of Mdmx loss can therefore be observed in a compromised p53 context in the absence of Cre expression. In the absence of Mdmx, the transcription of Mdm2 is stimulated to some extent, leading to slightly increased Mdm2 protein levels. Mdmx thus does not seem to affect Mdm2 protein stability significantly.

The contribution of Mdmx to the regulation of p53 transcriptional activity has become clearer. Genetic evidence indicates that Mdmx inhibits p53 transcriptional activity independently of Mdm2. Loss of Mdmx in cells lacking Mdm2 causes an increase in p53 activity in cultured mouse embryonic fibroblasts (MEFs) without a concomitant increase in p53 levels (Francoz et al., 2006). Analyses of p53^P regulation by Mdm2 and Mdmx produced similar results (Toledo et al., 2006). p53 interacts with the p300 histone acetyltransferase and this interaction appears to be essential for p53-dependent activation of the promoter of the p53-target gene p21 (Liu et al., 2003). p53 itself is acetylated by p300 on several lysine residues, and this modification is thought to increase its transcriptional activity (Prives and Manley, 2001). Interestingly, Mdmx decreases p300-mediated acetylation of p53 (Danovi et al., 2004; Sabbatini and McCormick, 2002), and endogenous p53 acetylation is increased in Mdmx-null cells (Migliorini et al., 2002b). Regardless, the exact nature of the mechanism through which Mdmx attenuates p53 transcriptional activity awaits further investigation. Moreover, one additional caveat is that all these studies were performed in cultured cells (MEFs) in which Mdmx protein levels were not examined, mainly owing to lack of high-affinity antibodies. The stability of Mdmx could be affected by manipulation of Mdm2 levels because Mdm2 can ubiquitylate Mdmx, which leads to its degradation (discussed below). In cells lacking both p53 and Mdm2, the Mdmx protein levels are increased compared with cells lacking p53 only (Meulmeester et al., 2005). It will, therefore, be essential in the future to assess endogenous Mdmx protein levels in such experiments.

View larger version (25K): [in this window] [in a new window]   Fig. 2. A model for cooperative control of the p53 pathway by Mdm2 and Mdmx. In the absence of stress signals, the primary function of Mdm2 is to maintain p53 at low levels, whereas Mdmx contributes to the overall inhibition of p53 independently of Mdm2. Mdmx inhibits p53 transcriptional activity, whereas the contribution of Mdm2 to the regulation of p53 transcriptional activity per se is still unclear and a matter of debate. The role of Cop-1 and Pirh2 in the regulation of p53 levels and activity in vivo is unclear, but recent data suggest that, if they participate in the regulation of this pathway, they can only do so in an Mdm2-dependent manner. See text for details.

Both Mdm2 and Mdmx have been implicated in regulation of the stability and/or activity of several other proteins that control cell proliferation, such as the retinoblastoma protein pRb, the heterodimer E2F1-DP1, Numb and Smads (Ganguli and Wasylyk, 2003; Marine and Jochemsen, 2005). However, the relevance of these interactions has not been firmly established genetically. Moreover, several lines of evidence argue against p53-independent functions of Mdm2 and Mdmx under physiological conditions. They do not exclude the possibility, however, that supra-physiological expression levels of these two proteins affect the activity of other proteins and p53-independent pathways. This possibility is interesting, since both proteins are aberrantly expressed in several human primary tumors (see below).

	Regulation of Mdmx expression and activity

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
As mentioned above, p53 is stabilized following cellular stress, such as DNA damage. Many mechanisms have been proposed (mostly involving phosphorylation) to regulate Mdm2-p53 interactions and/or Mdm2 activity (reviewed by Wahl, 2006). Only recently has insight into Mdmx regulation after DNA damage been obtained. In contrast to Mdm2, there is no evidence so far that transcription of Mdmx is affected by DNA damage, mitogens or any other cellular stress. Mdmx instead appears to be regulated mainly at the protein level. Several groups have shown that Mdm2 can bind to and ubiquitylate Mdmx to stimulate its proteasome-dependent degradation (Pan and Chen, 2003; de Graaf et al., 2003; Kawai et al., 2003).

Interestingly, in normal proliferating cells, MDM2 does not play a major role in regulation of MDMX stability. The MDMX protein is very stable, and knocking down MDM2 in cultured cells has little effect on the levels of MDMX (reviewed by Marine and Jochemsen, 2005). However, following DNA damage, MDMX levels rapidly decline in an MDM2-dependent manner. The Ataxia telangiectasia mutated (ATM) protein and checkpoint kinase 2 (Chk2) are key regulators of biological responses to DNA damage. Efficient degradation of MDMX following DNA damage requires ATM-dependent phosphorylation on S342 and S367 by Chk2 and S403 by ATM (Pereg et al., 2005; Chen, L. et al., 2005a; Okamoto et al., 2005; Pereg et al., 2006). Furthermore, UVC treatment results in Chk1-mediated phosphorylation of S367 (Jin et al., 2006). Phosphorylation of MDMX reduces its affinity for the deubiquitylating enzyme (DUB) HAUSP/USP7 (Meulmeester et al., 2005). Expression of HAUSP is essential for maintenance of both MDM2 and MDMX protein levels (Cummins et al., 2004; Li et al., 2004). MDM2 destabilization following DNA damage (Stommel and Wahl, 2004) is also the result of decreased HAUSP binding, whereas binding of p53 to HAUSP is not affected (Meulmeester et al., 2005). The destabilization of both MDMX and MDM2 is essential for proper p53 activation following DNA damage. The mechanism by which MDMX phosphorylations affect the MDMX-HAUSP interaction has not been elucidated. Clearly, loss of HAUSP binding might not be the only mechanism involved. For example, phosphorylation of both S342 and S367 creates binding sites for 14-3-3 protein. Interaction of 14-3-3 with MDMX is necessary for DNA-damage-induced nuclear accumulation and degradation of MDMX (LeBron et al., 2006; Pereg et al., 2006). It might also, however, affect binding to HAUSP.

Basal phosphorylation of Mdmx on Ser96 and Ser289 by CDK1 and CK1-, respectively, has also been reported (Elias et al., 2005; Chen, L. et al., 2005b). Phosphorylation of Ser96 is proposed to regulate Mdm2 localisation, whereas the CK1--mediated phosphorylation stimulates the Mdmx-p53 interaction by an unknown mechanism. Mdmx thus appears to be regulated primarily by post-translational modifications that affect its stability, subcellular localization and protein-protein interactions.

	MDMX contributes to tumorigenesis

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
Disruption of the p53 tumor suppressor pathway is as a result of mutation of the p53 gene in approximately 50% of cases. Tumors retaining wild-type p53 are thought to have defects either in effector target genes or in the expression of p53 regulators. One of the best examples of the latter class is MDM2, levels of which can be increased by gene amplification, enhanced transcription or increased translation. Several studies now implicate MDMX in tumor formation. A study on a large series of gliomas revealed that MDMX is amplified/overexpressed in 5/208 tumor samples (Riemenschneider et al., 1999) and that MDMX is the common amplified gene in the large amplicons (Riemenschneider et al., 2003). Furthermore, in approximately 30% of the tumor cell lines tested MDMX is either overexpressed or alternatively transcribed, and in general this correlates with the presence of wild-type p53 (Ramos et al., 2001). A recent analysis of a large series of tumors also revealed overexpression of MDMX in a significant percentage of several tumor types – for example, 19% of breast carcinomas (Danovi et al., 2004). In all cases, amplification of MDMX correlated with wild-type p53 status and lack of MDM2 amplification.

The importance of enhanced MDMX expression has been tested in the MCF-7 breast tumor cell line, which contains wild-type p53. Knocking down endogenous MDMX increases expression of p21, a p53-responsive gene product that negatively regulates progression through the cell cycle, without a significant increase in p53 levels. Colony assays showed that knocking down MDMX blocks proliferation of MCF-7 cells unless p53 levels are simultaneously decreased. Constitutive expression of Mdmx immortalizes MEFs in the absence of p53 mutation or loss of expression of ARF, a nucleolar protein that antagonizes Mdm2 functions (Sherr and Weber, 2000). Furthermore, Mdmx prevents oncogenic-Ras-induced premature senescence, and cells expressing Mdmx and activated Ras (Ras^V12) are oncogenic in nude mice (Danovi et al., 2004). MDMX thus functions as an oncogene when constitutively overexpressed, which can act as an alternative to p53 mutation in human tumors.

Many tumors contain aberrantly and/or alternatively spliced MDM2 variants. The effects of these variants are still unknown, but their expression is more common in high-grade than in low-grade tumors (Bartel et al., 2004). A systematic analysis of MDMX splice variants in large tumor sets is still lacking. However, two variants have been identified and partially characterized. The MDMX-S variant comprises only the p53-binding domain and a few alternative C-terminal amino acids. It is detected both in untransformed and transformed cells, and its expression is elevated when cells are stimulated to enter S-phase (Rallapalli et al., 1999). Owing to a higher affinity than full-length MDMX for p53 and to its increased nuclear localization, MDMX-S appears to be a very efficient inhibitor of p53 (Rallapalli et al., 1999; Rallapalli et al., 2003). MDMX-S is also more stable than MDMX, possibly because it can no longer interact with MDM2 and is, therefore, protected from MDM2-mediated degradation. Interestingly, an elevated MDMX-S/MDMX ratio has been reported in high-grade gliomas (Riemenschneider et al., 2003). Moreover, analysis of soft-tissue sarcomas indicated that high MDMX-S levels correlate with decreased survival and an increased risk of tumor-related death (Bartel et al., 2005).

Another splice variant, MDMX211, results from splicing between the exon 2 donor site and a cryptic splice acceptor site within exon 11 (Giglio et al., 2005). The resulting protein lacks the p53-binding domain but retains the RING-finger domain. Transfection and RNAi studies indicate that this protein has oncogenic activity possibly as a result of stabilization of MDM2. Although MDMX211 variant has been identified in 2/16 analyzed non-small-cell lung tumors, further studies are needed to establish its significance in human cancer.

	MDMX as a drug target in retinoblastoma

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
Retinoblastoma is a rare childhood cancer of the retina that initiates in utero during fetal development because of inactivation of the RB1 gene (Dyer and Harbour, 2006). Although the initiating genetic event (biallelic inactivation of RB1) is well established, the subsequent genetic events that contribute to retinoblastoma progression have not been well characterized. The status of the p53 pathway has been a topic of considerable debate in the field. Early studies on human tumors demonstrated that p53 is wild-type in retinoblastoma (Kato et al., 1996). However, exogenous p53 can induce cell death in retinoblastoma cell lines (Nork et al., 1997). In HPV-E7 transgenic mouse models of retinoblastoma, tumor development is greatly enhanced when p53 is inactivated (Howes et al., 1994). Recently, Zang et al. developed the first knockout mouse model of retinoblastoma (Zhang et al., 2004) by conditionally inactivating Rb1 in the developing retina of p107^–/– mice. As in the HPV-E7 transgenic mouse models, inactivation of p53 in retinal progenitor cells lacking Rb1 and p107 leads to an aggressive invasive form of retinoblastoma in mice that more faithfully recapitulates the human disease (Dyer et al., 2005). Inactivation of the p53 pathway is therefore likely to be an important step in retinoblastoma progression, but the p53 gene itself remains intact.

BAC-CGH, fluorescence in situ hybridization (FISH) and immunohistochemistry (IHC) studies reveal an increased MDMX copy number in 65% of human retinoblastomas, and MDM2 is amplified in an additional 10% of these tumors (Laurie et al., 2006). Genetic amplification of MDMX correlates with increased mRNA and protein levels and suppression of p53 target genes such as p21. MDMX regulates cell death and cell cycle exit in cultured retinoblastoma cells in a p53-dependent manner. Moreover, ectopic expression of MDMX in mouse Rb-null p107-null retinal progenitor cells leads to a reduction in p53-mediated apoptosis and clonal expansion of tumor cells. Similar studies of human fetal retinae demonstrate that ectopic expression of MDMX rescues p53-mediated cell death as a result of activation of the ARF oncogenic stress response pathway following RB1 gene inactivation. These experiments clearly show that the p53 pathway is suppressed in retinoblastoma cells following biallelic inactivation of RB1 and that a majority of tumors inactivate the p53 pathway through MDMX gene amplification (Fig. 3). In addition, they show that retinoblastoma does not arise from an intrinsically death-resistant cell as previously believed (Dyer and Bremner, 2005).

View larger version (27K): [in this window] [in a new window]   Fig. 3. Interactions between Rb, MDMX and p53 during retinoblastoma formation. (A) Biallelic inactivation of the RB1 gene is the initiating oncogenic event in retinoblastoma. As a consequence, the activity of transcription factors of the E2F family is unleashed, leading to increased S-phase entry and induction of ARF expression. ARF is induced in response to oncogenic stress and a direct E2F3a transcription target. ARF functions as an Mdm2 antagonist and therefore activates the p53 pathway. High ARF expression was indeed recently detected in RB1-deficient retinoblasts and, as a consequence, a high proportion of these cells undergo p53-mediated apoptosis. (B) The p53 pathway is suppressed during the formation of retinoblastoma and the majority of tumors inactivate this pathway through selective amplification and/or overexpression of MDMX.

	Concluding remarks and perspectives

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 
Mdmx primarily inhibits p53 by interfering with its transcriptional activity. Even if it is now clear that direct interaction between Mdmx and p53 appears essential, the molecular mechanism by which Mdmx regulates p53 activity has not been fully elucidated and should be. Mdmx not only interacts with p53 but also heterodimerizes with Mdm2. The relevance of this interaction in vivo has to be further examined since the existing mouse models have failed, so far, to support most transfection studies, which indicates that this interaction regulates Mdm2 and Mdmx protein stability. In view of its high degree of sequence conservation and its similarity with Mdm2, it is intriguing that the RING-finger domain of Mdmx appears incapable of inducing ubiquitylation and subsequent degradation of p53. It will be interesting to assess whether or not this domain is required only for the formation of Mdmx-Mdm2 complexes or if it is required for ubiquitylation of other substrates. In this context, it would be worth checking whether this domain can promote binding of Mdmx to E2 ubiquityl conjugases. Another major unknown is the relative abundance of the Mdm2 and Mdmx proteins and the stoichiometry of the different complexes that can be formed, such as p53-Mdm2, p53-Mdmx, Mdm2-Mdmx and possibly p53-Mdm2-Mdmx, in normal cells and cells under stress. In order to resolve this important issue, new tools will have to be generated, such as high-affinity anti-Mdmx antibodies and more elaborate mouse models – for instance, Mdm2 and Mdmx alleles expressing tagged proteins from the respective endogenous promoters. Knockin mutations should also be used to test the relevance of the ATM- and Chk2-phosphorylation sites described above.

There is now clear genetic evidence indicating that Mdmx contributes to the regulation of p53 independently of Mdm2 and that both proteins act synergistically to keep p53 in check (Francoz et al., 2006; Marine et al., 2006). Thus, activation of `dormant' p53 tumor suppressor activity in tumors with wild-type p53 is expected to be more efficient if one uses specific antagonists that can target both MDM2 and MDMX. Since nutlin-3 has only a poor affinity for Mdmx, we propose that new, specific Mdmx antagonists should be developed. Alternatively, if nutlin-3 can be delivered locally at a high enough concentration to inhibit both MDM2 and MDMX, then this treatment may be sufficient. A particularly clear illustration of the latter approach is the efficacy with which retinoblastoma development is impaired in a rat xenograft model upon subconjunctival delivery of nutlin-3. Moreover, by combining MDM2/MDMX antagonists with drugs that induce a p53 response through DNA damage (e.g. topotecan) this anti-tumor effect may be further enhanced.

One of the most common ways that the p53 pathway is inactivated in retinoblastomas is by increased MDMX expression through gene amplification. It is intriguing that the frequency of MDMX amplification is high in retinoblastoma compared with other tumor types (Danovi et al., 2004). This observation may be explained by the difference in the ability of ARF to bind to MDM2 and MDMX. Biochemical studies have shown that ARF can bind to MDM2 but not MDMX (Wang et al., 2001). Considering that ARF is directly regulated by RB1 (Aslanian et al., 2004), retinal cells lacking RB1 may have a greater degree of induction of ARF than tumors initiated by other disruptions in the Rb pathway – for instance, those involving p16, cyclin D1 or CDK4 (Sherr and McCormick, 2002). MDM2 amplification should therefore not lead to efficient inhibition of the p53 pathway in RB1-deficient retinal cells. In contrast, despite high levels of ARF, MDMX amplification would be expected to efficiently block the p53 cell death pathway in retinoblastoma because ARF does not bind MDMX. Additional experiments, including the generation of conditional Mdm2 and Mdmx mouse models, will be necessary to test further this hypothesis.

	References

Top Summary The p53-Mdm2 network Mdmx, an Mdm2-related protein Mdmx, another key gatekeeper... Regulation of Mdmx expression... MDMX contributes to... MDMX as a drug... Concluding remarks and... References

 

Aslanian, A., Iaquinta, P. J., Verona, R. and Lees, J. A. (2004). Repression of the Arf tumor suppressor by E2F3 is required for normal cell cycle kinetics. Genes Dev. 18, 1413-1422.[Abstract/Free Full Text]

Badciong, J. C. and Haas, A. L. (2002). MdmX is a RING finger ubiquitin ligase capable of synergistically enhancing Mdm2 ubiquitination. J. Biol. Chem. 277, 49668-49675.[Abstract/Free Full Text]

Barak, Y., Juven, T., Haffner, R. and Oren, M. (1993). mdm2 expression is induced by wild type p53 activity. EMBO J. 12, 461-468.[Medline]

Bartel, F., Harris, L. C., Wurl, P. and Taubert, H. (2004). MDM2 and its splice variant messenger RNAs: expression in tumors and down-regulation using antisense oligonucleotides. Mol. Cancer Res. 2, 29-35.[Abstract/Free Full Text]

Boesten, L. S., Zadelaar, S. M., De Clercq, S., Francoz, S., van Nieuwkoop, A., Biessen, E. A., Hofmann, F., Feil, S., Feil, R., Jochemsen, A. G. et al. (2006). Mdm2, but not Mdm4, protects terminally differentiated smooth muscle cells from p53-mediated caspase-3-independent cell death. Cell Death Differ. 13, 927-934.[CrossRef][Medline]

Bottger, V., Bottger, A., Garcia-Echeverria, C., Ramos, Y. F., van der Eb, A. J., Jochemsen, A. G. and Lane, D. P. (1999). Comparative study of the p53-mdm2 and p53-MDMX interfaces. Oncogene 18, 189-199.[CrossRef][Medline]

Cahilly-Snyder, L., Yang-Feng, T., Francke, U. and George, D. L. (1987). Molecular analysis and chromosomal mapping of amplified genes isolated from a transformed mouse 3T3 cell line. Somat. Cell Mol. Genet. 13, 235-244.[CrossRef][Medline]

Chen, D., Kon, N., Li, M., Zhang, W., Qin, J. and Gu, W. (2005). ARF-BP1/Mule is a critical mediator of the ARF tumor suppressor. Cell 121, 1071-1083.[CrossRef][Medline]

Chen, L., Gilkes, D. M., Pan, Y., Lane, W. S. and Chen, J. (2005a). ATM and Chk2-dependent phosphorylation of MDMX contribute to p53 activation after DNA damage. EMBO J. 24, 3411-3422.[CrossRef][Medline]

Chen, L., Li, C., Pan, Y. and Chen, J. (2005b). Regulation of p53-MDMX interaction by casein kinase 1 alpha. Mol. Cell. Biol. 25, 6509-6520.[Abstract/Free Full Text]

Cummins, J. M., Rago, C., Kohli, M., Kinzler, K. W., Lengauer, C. and Vogelstein, B. (2004). Tumour suppression: disruption of HAUSP gene stabilizes p53. Nature 428, 1 p following 486.[Medline]

Danovi, D., Meulmeester, E., Pasini, D., Migliorini, D., Capra, M., Francoz, S., Gasparini, P., Gobbi, A., Helin, K., Jochemsen, A. et al. (2004). Amplification of Mdmx (or Mdm4) directly contributes to tumour formation by inhibiting p53-tumour suppressor activity. Mol. Cell. Biol, 24, 5835-5843.[Abstract/Free Full Text]

de Graaf, P., Little, N. A., Ramos, Y. F. M., Meulmeester, E., Letteboer, S. J. and Jochemsen, A. G. (2003). Hdmx protein stability is regulated by the ubiquitin ligase activity of Mdm2. J. Biol. Chem. 278, 38315-38324.[Abstract/Free Full Text]

Dornan, D., Wertz, I., Shimizu, H., Arnott, D., Frantz, G. D., Dowd, P., O'Rourke, K., Koeppen, H. and Dixit, V. M. (2004). The ubiquitin ligase COP1 is a critical negative regulator of p53. Nature 429, 86-92.[CrossRef][Medline]

Doumont, G., Martoriati, A., Beekman, C., Bogaerts, S., Mee, P. J., Bureau, F., Colombo, M., Alcalay, M., Bellefroid, E., Marchesi, F. et al. (2005). G1 checkpoint failure and increased tumor susceptibility in mice lacking the novel p53 target Ptprv. EMBO J. 24, 3093-3103.[CrossRef][Medline]

Dyer, M. A. and Bremner, R. (2005). The search for the retinoblastoma cell of origin. Nat. Rev. Cancer 5, 91-101.[Medline]

Dyer, M. A. and Harbour, J. W. (2006). Cellular events in tumorigenesis. In Clinical Ocular Oncology (ed. A. D. Singh, B. E. Damato, A. L. Murphree and J. D. Perry). London: Elsevier.

Dyer, M. A., Rodriguez-Galindo, C. and Wilson, M. W. (2005). Use of preclinical models to improve treatment of retinoblastoma. PLoS Med. 2, e332.[CrossRef][Medline]

el-Deiry, W. S., Tokino, T., Velculescu, V. E., Levy, D. B., Parsons, R., Trent, J. M., Lin, D., Mercer, W. E., Kinzler, K. W. and Vogelstein, B. (1993). WAF1, a potential mediator of p53 tumor suppression. Cell 75, 817-825.[CrossRef][Medline]

Elias, B., Laine, A. and Ronai, Z. (2005). Phosphorylation of Mdmx by CDK2/Cdc2(p34) is required for nuclear export of Mdm2. Oncogene 24, 2574-2579.[CrossRef][Medline]

Finch, R. A., Donoviel, D. B., Potter, D., Shi, M., Fan, A., Freed, D. D., Wang, C. Y., Zambrowicz, B. P., Ramirez-Solis, R., Sands, A. T. et al. (2002). Mdmx is a negative regulator of p53 activity in vivo. Cancer Res. 62, 3221-3225.[Abstract/Free Full Text]

Francoz, S., Froment, P., Bogaerts, S., De Clercq, S., Maetens, M., Doumont, G., Bellefroid, E. and Marine, J. C. (2006). Mdm4 and Mdm2 cooperate to inhibit p53 activity in proliferating and quiescent cells in vivo. Proc. Natl. Acad. Sci. USA 103, 3232-3237.[Abstract/Free Full Text]

Ganguli, G. and Wasylyk, B. (2003). p53-independent functions of MDM2. Mol. Cancer Res. 1, 1027-1035.[Abstract/Free Full Text]

Giglio, S., Mancini, F., Gentiletti, F., Sparaco, G., Felicioni, L., Barassi, F., Martella, C., Prodosmo, A., Iacovelli, S., Buttitta, F. et al. (2005). Identification of an aberrantly spliced form of HDMX in human tumors: a new mechanism for HDM2 stabilization. Cancer Res. 65, 9687-9694.[Abstract/Free Full Text]

Grier, J. D., Yan, W. and Lozano, G. (2002). Conditional allele of mdm2 which encodes a p53 inhibitor. Genesis 32, 145-147.[CrossRef][Medline]

Grier, J. D., Xiong, S., Elizondo-Fraire, A. C., Parant, J. M. and Lozano, G. (2006). Tissue-specific differences of p53 inhibition by Mdm2 and Mdm4. Mol. Cell. Biol. 26, 192-198.[Abstract/Free Full Text]

Gu, J., Kawai, H., Nie, L., Kitao, H., Wiederschain, D., Jochemsen, A. G., Parant, J., Lozano, G. and Yuan, Z. M. (2002). Mutual dependence of MDM2 and MDMX in their functional inactivation of p53. J. Biol. Chem. 277, 19251-19254.[Abstract/Free Full Text]

Haupt, Y., Maya, R., Kazaz, A. and Oren, M. (1997). Mdm2 promotes the rapid degradation of p53. Nature 387, 296-299.[CrossRef][Medline]

Howes, K. A., Ransom, N., Papermaster, D. S., Lasudry, J. G., Albert, D. M. and Windle, J. J. (1994). Apoptosis or retinoblastoma: alternative fates of photoreceptors expressing the HPV-16 E7 gene in the presence or absence of p53. Genes Dev. 8, 1300-1310.[Abstract/Free Full Text]

Jackson, M. W. and Berberich, S. J. (2000). MdmX protects p53 from Mdm2-mediated degradation. Mol. Cell. Biol. 20, 1001-1007.[Abstract/Free Full Text]

Jin, Y., Dai, M. S., Lu, S. Z., Xu, Y., Luo, Z., Zhao, Y. and Lu, H. (2006). 14-3-3gamma binds to MDMX that is phosphorylated by UV-activated Chk1, resulting in p53 activation. EMBO J. 25, 1207-1218.[CrossRef][Medline]

Jones, S. N., Roe, A. E., Donehower, L. A. and Bradley, A. (1995). Rescue of embryonic lethality in Mdm2-deficient mice by absence of p53. Nature 378, 206-208.[CrossRef][Medline]

Kato, M. V., Shimizu, T., Ishizaki, K., Kaneko, A., Yandell, D. W., Toguchida, J. and Sasaki, M. S. (1996). Loss of heterozygosity on chromosome 17 and mutation of the p53 gene in retinoblastoma. Cancer Lett. 106, 75-82.[CrossRef][Medline]

Kawai, H., Wiederschain, D., Kitao, H., Stuart, J., Tsai, K. K. and Yuan, Z. M. (2003). DNA damage-induced MDMX degradation is mediated by MDM2. J. Biol. Chem. 278, 45946-45953.[Abstract/Free Full Text]

Kortlever, R. M., Higgins, P. J. and Bernards, R. (2006). Plasminogen activator inhibitor-1 is a critical downstream target of p53 in the induction of replicative senescence. Nat. Cell Biol. 8, 877-884.[Medline]

Kubbutat, M. H., Jones, S. N. and Vousden, K. H. (1997). Regulation of p53 stability by Mdm2. Nature 387, 299-303.[CrossRef][Medline]

Langheinrich, U., Hennen, E., Stott, G. and Vacun, G. (2002). Zebrafish as a model organism for the identification and characterization of drugs and genes affecting p53 signaling. Curr. Biol. 12, 2023-2038.[CrossRef][Medline]

Laurie, N. A., Donovan, S. L., Zhang, J., Shih, C.-S., Fuller, C. E., Teunisse, A., Johnson, D. A., Wilson, M. W., Rodriguez-Galindo, C., Quarto, M. et al. (2006). Inactivation of the p53 pathway in retinoblastoma. Nature 444, 61-66.[CrossRef][Medline]

LeBron, C., Chen, L., Gilkes, D. M. and Chen, J. (2006). Regulation of MDMX nuclear import and degradation by Chk2 and 14-3-3. EMBO J. 25, 1196-1206.[CrossRef][Medline]

Leng, R. P., Lin, Y., Ma, W., Wu, H., Lemmers, B., Chung, S., Parant, J. M., Lozano, G., Hakem, R. and Benchimol, S. (2003). Pirh2, a p53-induced ubiquitin-protein ligase, promotes p53 degradation. Cell 112, 779-791.[CrossRef][Medline]

Li, M., Brooks, C. L., Kon, N. and Gu, W. (2004). A dynamic role of HAUSP in the p53-Mdm2 pathway. Mol. Cell 13, 879-886.[CrossRef][Medline]

Linares, L. K., Hengstermann, A., Ciechanover, A., Muller, S. and Scheffner, M. (2003). HdmX stimulates Hdm2-mediated ubiquitination and degradation of p53. Proc. Natl. Acad. Sci. USA 100, 12009-12014.[Abstract/Free Full Text]

Liu, G., Xia, T. and Chen, X. (2003). The activation domains, the proline-rich domain, and the C-terminal basic domain in p53 are necessary for acetylation of histones on the proximal p21 promoter and interaction with p300/CREB-binding protein. J. Biol. Chem. 278, 17557-17565.[Abstract/Free Full Text]

Marine, J.-C. and Jochemsen, A. G. (2004). Mdmx and Mdm2: brothers in arms? Cell Cycle 3, 105-109.

Marine, J.-C. and Jochemsen, A. G. (2005). Mdmx as an essential regulator of p53 activity. Biochem. Biophys. Res. Commun. 331, 750-760.[CrossRef][Medline]

Marine, J.-C., Francoz, S., Maetens, M., Wahl, G., Toledo, F. and Lozano, G. (2006). Keeping p53 in check: essential and synergistic functions of Mdm2 and Mdm4. Cell Death Differ. 13, 927-934.[CrossRef][Medline]

McCoy, M. A., Gesell, J. J., Senior, M. M. and Wyss, D. F. (2003). Flexible lid to the p53-binding domain of human Mdm2: implications for p53 regulation. Proc. Natl. Acad. Sci. USA 100, 1645-1648.[Abstract/Free Full Text]

Mendrysa, S. M., McElwee, M. K., Michalowski, J., O'Leary, K. A., Young, K. M. and Perry, M. E. (2003). mdm2 Is critical for inhibition of p53 during lymphopoiesis and the response to ionizing irradiation. Mol. Cell. Biol. 23, 462-472.[Abstract/Free Full Text]

Meulmeester, E., Maurice, M. M., Boutell, C., Teunisse, A. F., Ovaa, H., Abraham, T. E., Dirks, R. W. and Jochemsen, A. G. (2005). Loss of HAUSP-mediated deubiquitination contributes to DNA damage-induced destabilization of Hdmx and Hdm2. Mol. Cell 18, 565-576.[CrossRef][Medline]

Michalak, E., Villunger, A., Erlacher, M. and Strasser, A. (2005). Death squads enlisted by the tumour suppressor p53. Biochem. Biophys. Res. Commun. 331, 786-798.[CrossRef][Medline]

Migliorini, D., Danovi, D., Colombo, E., Carbone, R., Pelicci, P.-G. and Marine, J.-C. (2002a). Hdmx recruitment into the nucleus by Hdm2 is essential for its ability to regulate p53 stability and transactivation. J. Biol. Chem. 277, 7318-7323.[Abstract/Free Full Text]

Migliorini, D., Lazzerini-Denchi, E., Danovi, D., Jochemsen, A., Capillo, M., Gobbi, A., Helin, K., Pelicci, P.-G. and Marine, J.-C. (2002b). Mdm4 (Mdmx) regulates p53-induced growth arrest and neuronal cell death during early embryonic mouse development. Mol. Cell. Biol. 22, 5527-5538.[Abstract/Free Full Text]

Minsky, N. and Oren, M. (2004). The RING domain of Mdm2 mediates histone ubiquitylation and transcriptional repression. Mol. Cell 16, 631-639.[CrossRef][Medline]

Momand, J., Zambetti, G. P., Olson, D. C., George, D. and Levine, A. J. (1992). The mdm-2 oncogene product forms a complex with the p53 protein and inhibits p53-mediated transactivation. Cell 69, 1237-1245.[CrossRef][Medline]

Montes de Oca Luna, R., Wagner, D. S. and Lozano, G. (1995). Rescue of early embryonic lethality in mdm2-deficient mice by absence of p53. Nature 378, 203-206.[CrossRef][Medline]

Nork, T. M., Poulsen, G. L., Millecchia, L. L., Jantz, R. G. and Nickells, R. W. (1997). p53 regulates apoptosis in human retinoblastoma. Arch. Ophthalmol. 115, 213-219.[Abstract]

Okamoto, K., Kashima, K., Pereg, Y., Ishida, M., Yamazaki, S., Nota, A., Teunisse, A., Migliorini, D., Kitabayashi, I., Marine, J.-C. et al. (2005). DNA damage-induced phosphorylation of MdmX at serine 367 activates p53 by targeting Mdmx for Mdm2-dependent degradation. Mol. Cell. Biol. 25, 9608-9620.[Abstract/Free Full Text]

Oliner, J. D., Kinzler, K. W., Meltzer, P. S., George, D. L. and Vogelstein, B. (1992). Amplification of a gene encoding a p53-associated protein in human sarcomas. Nature 358, 80-83.[CrossRef][Medline]

Pan, Y. and Chen, J. (2003). MDM2 promotes ubiquitination and degradation of MDMX. Mol. Cell. Biol. 23, 5113-5121.[Abstract/Free Full Text]

Pan, Y. and Chen, J. (2005). Modification of MDMX by sumoylation. Biochem. Biophys. Res. Commun. 332, 702-709.[CrossRef][Medline]

Parant, J., Chavez-Reyes, A., Little, N. A., Yan, W., Reinke, V., Jochemsen, A. G. and Lozano, G. (2001). Rescue of embryonic lethality in Mdm4-null mice by loss of Trp53 suggests a nonoverlapping pathway with MDM2 to regulate p53. Nat. Genet. 29, 92-95.[CrossRef][Medline]

Patton, J. T., Mayo, L. D., Singhi, A. D., Gudkov, A. V., Stark, G. R. and Jackson, M. W. (2006). Levels of HdmX expression dictate the sensitivity of normal and transformed cells to Nutlin-3. Cancer Res. 66, 3169-3176.[Abstract/Free Full Text]

Pereg, Y., Shkedy, D., de Graaf, P., Meulmeester, E., Edelson-Averbukh, M., Salek, M., Biton, S., Teunisse, A. F., Lehmann, W. D., Jochemsen, A. G. et al. (2005). Phosphorylation of Hdmx mediates its Hdm2- and ATM-dependent degradation in response to DNA damage. Proc. Natl. Acad. Sci. USA 102, 5056-5061.[Abstract/Free Full Text]

Pereg, Y., Lam, S., Teunisse, A., Biton, S., Meulmeester, E., Mittelman, L., Buscemi, G., Okamoto, K., Taya, Y., Shiloh, Y. et al. (2006). Differential roles of ATM- and Chk2-mediated phosphorylations of Hdmx in response to DNA damage. Mol. Cell. Biol. 26, 6819-6831.[Abstract/Free Full Text]

Prives, C. and Manley, J. L. (2001). Why is p53 acetylated? Cell 107, 815-818.[CrossRef][Medline]

Rallapalli, R., Strachan, G., Cho, B., Mercer, W. E. and Hall, D. J. (1999). A novel MDMX transcript expressed in a variety of transformed cell lines encodes a truncated protein with potent p53 repressive activity. J. Biol. Chem. 274, 8299-8308.[Abstract/Free Full Text]

Rallapalli, R., Strachan, G., Tuan, R. S. and Hall, D. J. (2003). Identification of a domain within MDMX-S that is responsible for its high affinity interaction with p53 and high-level expression in mammalian cells. J. Cell. Biochem. 89, 563-575.[CrossRef][Medline]

Ramos, Y. F. M., Stad, R., Attema, J., Peltenburg, L. T., van der Eb, A. J. and Jochemsen, A. G. (2001). Aberrant expression of HDMX proteins in tumor cells correlates with wild-type p53. Cancer Res. 61, 1839-1842.[Abstract/Free Full Text]

Riemenschneider, M. J., Buschges, R., Wolter, M., Reifenberger, J., Bostrom, J., Kraus, J. A., Schlegel, U. and Reifenberger, G. (1999). Amplification and overexpression of the MDM4 (MDMX) gene from 1q32 in a subset of malignant gliomas without TP53 mutation or MDM2 amplification. Cancer Res. 59, 6091-6096.[Abstract/Free Full Text]

Riemenschneider, M. J., Knobbe, C. B. and Reifenberger, G. (2003). Refined mapping of 1q32 amplicons in malignant gliomas confirms MDM4 as the main amplification target. Int. J. Cancer 104, 752-757.[CrossRef][Medline]

Sabbatini, P. and McCormick, F. (2002). MDMX inhibits the p300/CBP-mediated acetylation of p53. DNA Cell Biol. 21, 519-525.[CrossRef][Medline]

Sharp, D. A., Kratowicz, S. A., Sank, M. J. and George, D. L. (1999). Stabilization of the MDM2 oncoprotein by interaction with the structurally related MDMX protein. J. Biol. Chem. 274, 38189-38196.[Abstract/Free Full Text]

Sherr, C. J. and McCormick, F. (2002). The RB and p53 pathways in cancer. Cancer Cell 2, 103-112.[CrossRef][Medline]

Sherr, C. J. and Weber, J. D. (2000). The ARF/p53 pathway. Curr. Opin. Genet. Dev. 10, 94-99.[CrossRef][Medline]

Shvarts, A., Steegenga, W. T., Riteco, N., van Laar, T., Dekker, P., Bazuine, M., van Ham, R. C., van der Houven van Oordt, W., Hateboer, G., van der Eb, A. J. et al. (1996). MDMX: a novel p53-binding protein with some functional properties of MDM2. EMBO J. 15, 5349-5357.[Medline]

Shvarts, A., Bazuine, M., Dekker, P., Ramos, Y. F., Steegenga, W. T., Merckx, G., van Ham, R. C., van der Houven van Oordt, W., van der Eb, A. J. and Jochemsen, A. G. (1997). Isolation and identification of the human homolog of a new p53-binding protein, Mdmx. Genomics 43, 34-42.[CrossRef][Medline]

Stad, R., Ramos, Y. F. M., Little, N., Grivell, S., Attema, J., van der Eb, A. J. and Jochemsen, A. G. (2000). Hdmx stabilizes Mdm2 and p53. J. Biol. Chem. 275, 28039-28044.[Abstract/Free Full Text]

Stad, R., Little, N. A., Xirodimas, D. P., Frenk, R., van der Eb, A. J., Lane, D. P., Saville, M. K. and Jochemsen, A. G. (2001). Mdmx stabilizes p53 and Mdm2 via two distinct mechanisms. EMBO Rep. 2, 1029-1034.[CrossRef][Medline]

Steinman, H. A. and Jones, S. N. (2002). Generation of an Mdm2 conditional allele in mice. Genesis 32, 142-144.[CrossRef][Medline]

Steinman, H. A., Hoover, K. M., Keeler, M. L., Sands, A. T. and Jones, S. N. (2005). Rescue of Mdm4-deficient mice by Mdm2 reveals functional overlap of Mdm2 and Mdm4 in development. Oncogene 24, 7935-7940.[CrossRef][Medline]

Stommel, J. M. and Wahl, G. M. (2004). Accelerated MDM2 auto-degradation induced by DNA-damage kinases is required for p53 activation. EMBO J. 23, 1547-1556.[CrossRef][Medline]

Tanimura, S., Ohtsuka, S., Mitsui, K., Shirouzu, K., Yoshimura, A. and Ohtsubo, M. (1999). MDM2 interacts with MDMX through their RING finger domains. FEBS Lett. 447, 5-9.[CrossRef][Medline]

Thut, C. J., Goodrich, J. A. and Tjian, R. (1997). Repression of p53-mediated transcription by MDM2: a dual mechanism. Genes Dev. 11, 1974-1986.[Abstract/Free Full Text]

Toledo, F., Krummel, K. A., Lee, C. J., Liu, C. W., Rodewald, L. W., Tang, M. and Wahl, G. M. (2006). A mouse p53 mutant lacking the proline-rich domain rescues Mdm4 deficiency and provides insight into the Mdm2-Mdm4-p53 regulatory network. Cancer Cell 9, 273-285.[CrossRef][Medline]

Vassilev, L. T., Vu, B. T., Grave