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The MDM2 oncoprotein targets the p53 tumor suppressor protein for degradation when the two proteins are expressed in cells. The regulation of p53 levels by MDM2 requires the ability of MDM2 to be exported from the nucleus by utilizing its nuclear export signal (NES). The drug leptomycin B (LMB) blocks the formation of nuclear export complexes consisting of CRM1, RanGTP, and NES-containing proteins. It is predicted that LMB should inhibit nuclear-cytoplasmic shuttling by MDM2 and subsequently stabilize p53. This communication demonstrates that LMB treatment of various cell lines led to an increase in the steady-state levels of the p53 protein as a result of an increase in its stability. The stabilized p53 protein localized to the nucleus and was an active transcription factor. These results indicate that the low steady-state levels of p53 in the absence of DNA damage result from p53's nuclear export for cytoplasmic degradation. LMB also led to p53 stabilization in cell lines that contain human papillomavirus (HPV) DNA and express HPV E6, a protein that targets p53 for degradation. MDM2 is not necessary for E6-dependent degradation of p53, as evidenced by the observation that E6 promoted p53 degradation in cells lacking endogenous MDM2. In addition, LMB reduced E6's ability to degrade p53 in the absence of MDM2, demonstrating that complete degradation of p53 by E6 requires nuclear export and therefore likely occurs in cytoplasmic proteasomes. These data suggest that the nuclear export of p53 to the cytoplasm for degradation is a general mechanism for regulating p53 levels.
Mol Cell Biol 1998 Dec
PMID:Nuclear export is required for degradation of endogenous p53 by MDM2 and human papillomavirus E6. 981 15

The p53 protein is activated in response to physiological stress resulting in either a G1 arrest of cells or apoptosis. As such, p53 must be tightly regulated, and the MDM2 oncoprotein plays a central role in that regulatory process. The transcription of the Mdm2 oncogene is induced by the p53 protein after DNA damage, and the MDM2 protein then binds to p53 and blocks its activities as a tumour suppressor and promotes its degradation. These two proteins thus form an autoregulatory feedback loop in which p53 positively regulates MDM2 levels and MDM2 negatively regulates p53 levels and activity. Immediately after ultraviolet (UV) irradiation MDM2 messenger RNA and protein levels fall in a p53-independent fashion, resulting in increased p53 levels. The p53 protein is then activated as a transcription factor by posttranslational modification permitting p53 to initiate its cell-cycle arrest or apoptotic (programmed cell death) functions. At later times, after the repair of DNA, MDM2 levels increase in a p53-dependent fashion. This induction of MDM2 results in the inhibition of p53 transcriptional activity and the degradation of p53 protein. MDM2-p53 complexes in the nucleus are transported to the cytoplasm via signals present in the MDM2 protein, where p53 is degraded in the proteasome. Thus MDM2 acts as a nuclear-cytoplasmic shuttle for the p53 protein. There are many levels at which this process is regulated, and as such there are many places for chemotherapeutic interventions. The amino-terminal domain of the MDM2 protein is all that is required to bind the p53 protein. The MDM2 protein has additional domains and therefore may have additional functions. Any of these MDM2 domains may contribute to MDM2's activities as an oncogene independent of its inhibition of the tumour suppressor functions of p53. Thus MDM2 itself could be a target for cancer therapeutic intervention.
Cell Mol Life Sci 1999 Jan
PMID:Functions of the MDM2 oncoprotein. 1006 55

The binding of RB to MDM2 is shown to be essential for RB to overcome both the antiapoptotic function of MDM2 and the MDM2-dependent degradation of p53. The RB-MDM2 interaction does not prevent MDM2 from inhibiting p53-dependent transcription, but the RB-MDM2 complex still binds to p53. Since RB specifically rescues the apoptotic function but not the transcriptional activity of p53 from negative regulation by MDM2, transactivation by wild-type p53 is not required for the apoptotic function of p53. However, an RB-MDM2-p53 trimeric complex is active in p53-mediated transrepression. These data link directly the function of two tumor suppressor proteins and demonstrate a novel role of RB in regulating the apoptotic function of p53.
Mol Cell 1999 Feb
PMID:RB regulates the stability and the apoptotic function of p53 via MDM2. 1007 1

The newly identified p53 homolog p73 can mimic the transcriptional activation function of p53. We investigated whether p73, like p53, participates in an autoregulatory feedback loop with MDM2. p73 bound to MDM2 both in vivo and in vitro. Wild-type but not mutant MDM2, expressed in human p53 null osteosarcoma Saos-2 cells, inhibited p73- and p53-dependent transcription driven by the MDM2 promoter-derived p53RE motif as measured in transient-transfection and chloramphenicol acetyltransferase assays and also inhibited p73-induced apoptosis in p53-null human lung adenocarcinoma H1299 cells. MDM2 did not promote the degradation of p73 but instead disrupted the interaction of p73, but not of p53, with p300/CBP by competing with p73 for binding to the p300/CBP N terminus. Both p73alpha and p73beta stimulated the expression of the endogenous MDM2 protein. Hence, MDM2 is transcriptionally activated by p73 and, in turn, negatively regulates the function of this activator through a mechanism distinct from that used for p53 inactivation.
Mol Cell Biol 1999 May
PMID:MDM2 suppresses p73 function without promoting p73 degradation. 1020 51

Multiple adenovirus (Ad) early proteins have been shown to inhibit transcription activation by p53 and thereby to alter its normal biological functioning. Since these Ad proteins affect the activity of p53 via different mechanisms, we examined whether this inhibition is target gene specific. In addition, we analyzed whether the same Ad early proteins have a comparable effect on transcription activation by the recently identified p53 homologue p73. Our results show that the large E1B proteins very efficiently inhibited the activity of p53 on the Bax, p21(Waf1), cyclin G, and MDM2 reporter constructs but had no effect on the activation of the same reporter constructs by p73, with the exception of some inhibition of the Bax promoter by Ad12 E1B. The repressive effect of the E1A proteins on p53 activity is less than that seen with the large E1B proteins, but the E1A proteins inhibit the activity of both p53 and p73. We could not detect significant inhibition of p53 functions by E4orf6, but a clear repression of the transcription activation by p73 by this Ad early protein was observed. In addition, we found that stable expression of the Ad5 E1A and that of the E1B protein both caused increased p73 protein expression. The large E1B and the E4orf6 proteins together do not target the p73 protein for rapid degradation after adenoviral infection, as has previously been found for the p53 protein, probably because the large E1B protein does not interact with p73. Our results suggest that the p53 and p73 proteins are both inactivated after Ad infection and transformation but via distinct mechanisms.
Mol Cell Biol 1999 May
PMID:Distinct regulation of p53 and p73 activity by adenovirus E1A, E1B, and E4orf6 proteins. 1020 12

The mammalian ARF-INK4a locus uniquely encodes two cell cycle inhibitors by using separate promoters and alternative reading frames. p16INK4a maintains the retinoblastoma protein in its growth suppressive state while ARF stabilizes p53. We report that human ARF protein predominantly localizes to the nucleolus via a sequence within the exon 2-encoded C-terminal domain and is induced to leave the nucleolus by MDM2. ARF forms nuclear bodies with MDM2 and p53 and blocks p53 and MDM2 nuclear export. Tumor-associated mutations in ARF exon 2 disrupt ARF's nucleolus localization and reduce ARF's ability to block p53 nuclear export and to stabilize p53. Our results suggest an ARF-regulated MDM2-dependent p53 stabilization and link the human tumor-associated mutations in ARF with a functional alteration.
Mol Cell 1999 May
PMID:Mutations in human ARF exon 2 disrupt its nucleolar localization and impair its ability to block nuclear export of MDM2 and p53. 1036 Jan 74

It is shown here that the N-terminal domain of MDM2, which is not thought to bind calcium ions, otherwise bears a striking resemblance to a cluster of four EF-hand modules like those found in the calmodulin family. There are similarities in module arrangement, supersecondary structure and the main-chain to main-chain hydrogen-bonding pattern, especially in the vicinity of the short antiparallel beta-sheet, the two strands of which lie between the two E and F helices of tandem modules. Some conserved amino acid residues are identified that are associated with short side-chain to main-chain hydrogen-bonded motifs. Also, both types of domain bind a short, functionally important hydrophobic alpha-helix from another protein in a cavity between the two pairs of EF-hand, or EF-hand-like, modules.
J Mol Biol 1999 Oct 08
PMID:The N-terminal domain of MDM2 resembles calmodulin and its relatives. 1051 95

Recent observations indicate the existence of pathogenetically distinct groups of well-differentiated (WD) dedifferentiated (DD) liposarcomas. In the retroperitoneal WD-DD liposarcomas, the predominant phenotype is represented by the aberrant (overexpressed) mdm2+/p53+ wild-type profile. At the nonretroperitoneal site, the WD liposarcomas present a wider association of MDM2/P53 gene expression; i.e., mdm2+/p53+, mdm2+/p53-, mdm2-/p53+ and mdm2-/p53-, and TP53 mutations seem to correlate with the dedifferentiation process. A biochemical study of mdm2-p53 association in 11 tumor samples characterized by the presence of different mdm2 and p53 immunophenotypes was performed. Immunoprecipitation assays using a p53-specific antibody were performed on tumor tissue and surrounding normal tissue; the immunoprecipitated material was then investigated for the presence of p53 (control) and of coimmunoprecipitated mdm2. This biochemical analysis showed that, in mdm2+/p53+/wild-type retroperitoneal liposarcomas, a band corresponded to mdm2 protein in the cellular lysates immunoprecipitated with a p53-directed antibody. In contrast, the mdm2+/p53- liposarcoma did not evidence the presence of mdm2 protein nor was p53 protein available to direct immunoprecipitation, as in the p53 mutant tumor samples with mdm2-/p53+ and mdm2-/p53- phenotypes. From the normal counterpart of retroperitoneal liposarcoma lysates, no p53 protein was immunoprecipitated. The findings in this study agree with the molecular data and they show the physical association of mdm2 and p53 in fresh liposarcoma surgical specimens.
Diagn Mol Pathol 1999 Sep
PMID:Biochemical uncovering of mdm2/p53 complexes in liposarcomas parallels their immunohistochemical detection. 1056 83

Rat-1 cells are used in many studies on transformation, cell cycle, and apoptosis. Whereas UV treatment of Rat-1 cells results in apoptosis, X-ray treatment does not induce either apoptosis or a cell cycle block. X-ray treatment of Rat-1 cells results in both an increase of p53 protein and expression of the p53-inducible gene MDM2 but not the protein or mRNA of the p53-inducible p21(WAF1/CIP1) gene, which in other cells plays an important role in p53-mediated cell cycle block. The lack of p21(WAF1/CIP1) expression appears to be the result of hypermethylation of the p21(WAF1/CIP1) promoter region, as p21(WAF1/CIP1) protein expression could be induced by growth of Rat-1 cells in the presence of 5-aza-2-deoxycytidine. Furthermore, sequence analysis of bisulfite-treated DNA demonstrated extensive methylation of cytosine residues in CpG dinucleotides in a CpG-rich island in the promoter region of the p21(WAF1/CIP1) gene. Stable X-ray-induced p53-dependent p21(WAF1/CIP1) expression and cell cycle block were restored to a Rat-1 clone after transfection with a P1 artificial chromosome (PAC) DNA clone containing a rat genomic copy of the p21(WAF1/CIP1) gene. The absence of expression of the p21(WAF1/CIP1) gene may contribute to the suitability of Rat-1 cells for transformation, cell cycle, and apoptosis studies.
Mol Cell Biol 2000 Feb
PMID:The p21(WAF1/CIP1) promoter is methylated in Rat-1 cells: stable restoration of p53-dependent p21(WAF1/CIP1) expression after transfection of a genomic clone containing the p21(WAF1/CIP1) gene. 1064 15

MDM2 is an important regulator of the p53 tumor suppressor protein. MDM2 inhibits p53 by binding to it, physically blocking its ability to transactivate gene expression, and stimulating its degradation. In cultured cells, mdm2 expression can be regulated by p53. Hence, mdm2 and p53 can interact to form an autoregulatory loop in which p53 activates expression of its own inhibitor. The p53/MDM2 autoregulatory loop has been elucidated within cultured cells; however, regulation of mdm2 expression by p53 has not been demonstrated within intact tissues. Here, we examine the role of p53 in regulating mdm2 expression in vivo in order to test the hypothesis that the p53/MDM2 autoregulatory loop is the mechanism by which low levels of p53 are maintained. We demonstrate that basal expression of mdm2 in murine tissues is p53 independent, even in tissues that express functional p53. Transcription of mdm2 is induced in a p53-dependent manner following gamma irradiation, indicating that p53 regulates mdm2 expression in vivo following a stimulus. The requirement for a stimulus to activate p53-dependent regulation of mdm2 expression in vivo appeared to differ from the situation in early-passage mouse embryo fibroblasts, where mdm2 expression is enhanced by the presence of p53. Analysis of mdm2 expression in intact and dispersed embryos revealed that establishment of mouse embryo fibroblasts in culture induces p53-dependent mdm2 expression, suggesting that an unknown stimulus activates p53 function in cultured cells. Together, these results indicate that p53 does not regulate expression of its own inhibitor, except in response to stimuli.
Mol Cell Biol 2000 Mar
PMID:The p53 tumor suppressor protein does not regulate expression of its own inhibitor, MDM2, except under conditions of stress. 1068 49

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