Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The MDM2 proto-oncogene is found amplified in a variety of tumours. The oncogenic capacity of the MDM2 protein is attributed to its ability to bind the p53 tumour-suppressor protein and mask its transcriptional activation potential. Here we show that MDM2 makes a functional contact with two cooperating transcription factors, E2F1 and DP1 (refs 4,5), which are involved in S-phase progression. MDM2 contacts the activation domain of E2F1 using residues conserved in the activation domain of p53. However, in contrast to its repression of p53 activity, MDM2 stimulates the activation capacity of E2F1/DP1. These results indicate that MDM2 not only releases a proliferative block by silencing the tumour suppressor p53, it also positively augments proliferation by stimulating the S-phase inducing transcription factors E2F1/DP1.
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PMID:Stimulation of E2F1/DP1 transcriptional activity by MDM2 oncoprotein. 779 3

One way in which wild-type p53 is able to regulate cell cycle progression is thought to be via the induction of its downstream target gene Waf1/CIP1, thus indirectly regulating the transcriptional activity of E2F. The E2F transcription factors are known to be key effectors of the cell cycle. We report here that there is a physical and functional interaction between p53 and two of the components of the E2F transcription factors, E2F1 and DP1. The expression of wild-type p53 can inhibit the transcriptional activity of E2F, and the expression of both E2F1 and DP1 can also downregulate p53-dependent transcription. The transcriptional activity of p53 is known to be inhibited by the direct binding of mdm2, but we demonstrate here that both E2F1 and DP1 can inhibit p53 transcriptional activity independently of mdm2. Detailed studies of protein-protein interactions have provided evidence that E2F1 and its co-operating factor DP1 can complex with p53 both in vitro and in vivo.
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PMID:Physical and functional interactions between p53 and cell cycle co-operating transcription factors, E2F1 and DP1. 855 38

The Mdm2 oncoprotein forms a complex with the p53 tumor suppressor protein and inhibits p53-mediated regulation of heterologous gene expression. Recently, Mdm2 has been found to bind several other proteins that function to regulate cell cycle progression, including the E2F-1/DP1 transcription factor complex and the retinoblastoma tumor-suppressor protein. To determine whether Mdm2 plays a role in cell cycle control or tumorigenesis that is distinct from its ability to modulate p53 function, we have examined and compared both the in vitro growth characteristics of p53-deficient and Mdm2/p53-deficient fibroblasts, and the rate and spectrum of tumor formation in p53-deficient and Mdm2/p53-deficient mice. We find no difference between p53-deficient fibroblasts and Mdm2/p53-deficient fibroblasts either in their rate of proliferation in culture or in their survival frequency when treated with various genotoxic agents. Cell cycle studies indicate no difference in the ability of the two cell populations to enter S phase when treated with DNA-damaging agents or nucleotide antimetabolites, and p53-deficient fibroblasts and Mdm2/p53-deficient fibroblasts exhibit the same rate of spontaneous immortalization following long-term passage in culture. Finally, p53-deficient mice and Mdm2/p53-deficient mice display the same incidence and spectrum of spontaneous tumor formation in vivo. These results demonstrate that deletion of Mdm2 has no additional effect on cell proliferation, cell cycle control, or tumorigenesis when p53 is absent.
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PMID:The tumorigenic potential and cell growth characteristics of p53-deficient cells are equivalent in the presence or absence of Mdm2. 894 68

The mouse double minute 2 (mdm2) proto-oncogene was originally discovered as one of three genes that was amplified in a tumorigenic cell line derived from non-transformed Balb/c cells. Consistent with the expression pattern of mdm2 in these cells, it was later shown that the transforming potential of the mdm2 proto-oncogene can be activated by experimental overexpression. Overexpression of mdm2 protein been detected in a number of diverse human malignancies, indicating that this oncogene plays a key role in human carcinogenesis. One mechanism by which mdm2 overexpression may lead to uncontrolled cellular proliferation is through its ability to physically associate with the p53 tumor suppressor and block p53's growth suppressive functions. Forced overexpression of mdm2 has been shown to block the transactivation, cell cycle arrest and apoptotic functions of p53. The mdm2 gene has also been shown to be a transcriptional target of p53 and the induction of p53 transcriptional activity leads to increases in mdm2 RNA and protein levels. Thus, it appears that an auto-regulatory feedback loop exists between these two proteins which keeps the growth suppressive functions of p53 in check during normal cell cycling. However, this block is thought to be overcome during certain cellular insults, including DNA damage, so that p53 can regulate the expression of genes involved in cell cycle arrest and/or apoptosis. Genetic lesions leading to elevated levels of mdm2 likely impair the ability of p53 to orchestrate the expression of genes controlling cell cycle progression during cellular insults. This may lead to the propagation of genetic errors, genomic instability and ultimately to an increase in the rate of tumor cell evolution. There is also recent evidence which suggests that mdm2 may play roles in p53-independent pathways regulating cellular proliferation. mdm2 has recently been shown to interact with the retinoblastoma tumor suppressor protein p(Rb), and the E2F-1 and DP1 transcription factors. These, and other clinical, cellular and biochemical studies relating to the mdm2 oncogene are reviewed here. In addition, a proposed role for mdm2 in pathways controlling cell cycle response to cellular perturbations is presented.
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PMID:The mdm2 proto-oncogene. 932 85

Cell cycle progression is subject to several regulatory controls, of which the p53 protein plays a major role in growth arrest, subsequent to the detection of cellular aberrations. It is well documented that p53 has the ability to inhibit transcription driven by several promoters, possibly via distinct mechanisms. In this report, we show that expression of the cell cycle regulatory transcription factor DP1 is strongly inhibited by p53, at the level of transcription and probably through the basal TATA-less promoter. This inhibitory activity has a relative specificity for the DP1 promoter compared with the functionally related E2F1 promoter or unrelated promoters such as those of the transcription factor ATFa or the thymidine kinase gene. Inhibition of DP1 transcription has implications in one of the several possible mechanisms through which p53 induces cell cycle arrest.
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PMID:The p53 tumor suppressor inhibits transcription of the TATA-less mouse DP1 promoter. 955 76

The mdm2 gene is positively regulated by p53 through a p53-responsive DNA element in the first intron of the mdm2 gene. mdm2 binds p53, thereby abrogating the ability of p53 to activate the mdm2 gene, and thus forming an autoregulatory loop of mdm2 gene regulation. Although the mdm2 gene is thought to act as an oncogene by blocking the activity of p53, recent studies indicate that mdm2 can act independently of p53 and block the G1 cell cycle arrest mediated by members of the retinoblastoma gene family and can activate E2F1/DP1 and the cyclin A gene promoter. In addition, factors other than p53 have recently been shown to regulate the mdm2 gene. In this article, we report that thyroid hormone (T3) receptors (T3Rs), but not the closely related members of the nuclear thyroid hormone/retinoid receptor gene family (retinoic acid receptor, vitamin D receptor, peroxisome proliferation activation receptor, or retinoid X receptor), regulate mdm2 through the same intron sequences that are modulated by p53. Chicken ovalbumin upstream promoter transcription factor I, an orphan nuclear receptor which normally acts as a transcriptional repressor, also activates mdm2 through the same intron region of the mdm2 gene. Two T3R-responsive DNA elements were identified and further mapped to sequences within each of the p53 binding sites of the mdm2 intron. A 10-amino-acid sequence in the N-terminal region of T3Ralpha that is important for transactivation and interaction with TFIIB was also found to be important for activation of the mdm2 gene response element. T3 was found to stimulate the endogenous mdm2 gene in GH4C1 cells. These cells are known to express T3Rs, and T3 is known to stimulate replication of these cells via an effect in the G1 phase of the cell cycle. Our findings, which indicate that T3Rs can regulate the mdm2 gene independently of p53, provide an explanation for certain known effects of T3 and T3Rs on cell proliferation. In addition, these findings provide further evidence for p53-independent regulation of mdm2 which could lead to the development of tumors from cells that express low levels of p53 or that express p53 mutants defective in binding to and activating the mdm2 gene.
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PMID:Regulation of the mdm2 oncogene by thyroid hormone receptor. 985 9

The p53 tumour suppressor is frequently inactivated in human tumours. One form of inactivation results from overexpression of MDM2, that normally forms a negative auto-regulatory loop with p53 and inhibits its activity through complex formation. We have investigated whether disrupting the MDM2-p53 complex in cells that overexpress MDM2 is sufficient to trigger p53 mediated cell death. We find that expression of a peptide homologue of p53 that binds to MDM2 leads to increased p53 levels and transcriptional activity. The consequences are increased expression of the downstream effectors MDM2 and p21WAF1/CIP1, inhibition of colony formation, cell cycle arrest and cell death. There is also a decrease in E2F activity, that might have been due to the known physical and functional interactions of MDM2 with E2F1/DP1. However, this decrease is p53 dependent, as are also colony formation, cell cycle arrest and cell death. These results show that a peptide homologue of p53 is sufficient to induce p53 dependent cell death in cells overexpressing MDM2, and support the notion that disruption of the p53-MDM2 complex is a target for the development of therapeutic agents.
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PMID:p53 mediated death of cells overexpressing MDM2 by an inhibitor of MDM2 interaction with p53. 1020 14

We recently reported that E2F1 could transactivate the p21 promoter via cis-acting elements between -119 to +16 bp of the p21 gene. Here we show that activated V12-H-Ras can induce the p21 promoter through the same region of the p21 promoter by a p53-independent mechanism in NIH3T3 cells. In contrast, activated Ras was not able to induce the p21 promoter in E2F1-/- fibroblasts, suggesting that E2F1 is required for induction of the p21 promoter by activated Ras. Cotransfection of increasing concentrations of dominant negative E2F1 alone, or with dominant negative DP1 into NIH3T3 cells suppressed induction of the p21 promoter by activated Ras. These data suggest that p53-independent induction of the p21 promoter by activated Ras is mediated at least in part by E2F1. Oncogene (2000) 19, 961 - 964.
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PMID:A role for E2F1 in Ras activation of p21(WAF1/CIP1) transcription. 1070 5

p73, a member of the p53 family, is overexpressed in many cancers. To understand the mechanism(s) underlying this overexpression, we have undertaken a detailed characterization of the human p73 promoter. The promoter is strongly activated in cells expressing exogenous E2F1 and suppressed by exogenous Rb. At least three functional E2F binding sites, located immediately upstream of exon 1 (at -284, -155 and -132) mediate this induction. 5' serially deleted promoter constructs and constructs harboring mutated E2F sites were analyzed for their response to exogenously expressed E2F1 or Rb to establish functionality of these sites. Authenticity of E2F sites was further confirmed by electrophoretic mobility shift assay (EMSA) using E2F1/DP1 heterodimers synthesized in vitro, followed by competition assays with unlabeled wild-type or mutant oligonucleotides and supershift analysis using anti-E2F1 antibodies. In vivo binding of E2F1 to the p73 promoter was demonstrated using nuclear extracts prepared from E2F1-inducible Saos2 cells. The region conferring the highest promoter activity was found to reside between -113 to -217 of the p73 gene. Two of the three functional E2F sites (at -155 and -132) reside within this region. Our results suggest that regulation of p73 expression is primarily mediated through binding of E2F1 to target sites at -155 and -132.
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PMID:The human p73 promoter: characterization and identification of functional E2F binding sites. 1198 39

The transcription factor E2F1 functions as a key regulator for both cell-cycle progression and apoptosis. Mdm2, a major cellular regulator of the p53 tumor suppressor protein, is also closely involved in cell cycle and apoptosis. In addition to regulation of p53, Mdm2 has been reported to stimulate E2F1 transactivation by a mechanism that remains unclear. Here we examined how overexpression of Mdm2 alters E2F1/DP1 transactivation. Using a set of cell lines with differing p53 and Rb status we determined that Mdm2 induction of E2F1 transactivation was p53-dependent, resulting from release of repression by p53. While Mdm2 association with p53 was required to increase E2F1 transactivation, Mdm2 mediated degradation of p53 was not. p53 repression of E2F1 transactivation required a functional DNA binding and transactivation domain. Consistent with Mdm2 activation of E2F1 via an inhibition of p53 transactivation we demonstrate a concomitant reduction in p21 protein levels with Mdm2 overexpression. Furthermore, E2F1 repression by an Rb-phosphorylation mutant could not be reversed by Mdm2 overexpression. Mdm2 was also unable to enhance E2F1 transactivation in Mouse embryo fibroblasts lacking p21. Taken together, these results suggest that Mdm2 activation of E2F1 occurs through the repression of p53-dependent transcription of p21, a p53-target gene and cyclin dependent kinase inhibitor.
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PMID:Mdm2 inhibition of p53 induces E2F1 transactivation via p21. 1208 Apr 72


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