UNIPROT:P04637 - FACTA Search

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

The p53 tumor suppressor is a universal sensor of genotoxic stress that regulates the transcription of genes required for cell-cycle arrest and apoptosis. In response to DNA damage, the p53 protein is phosphorylated at its amino-terminus and becomes stabilized upon disruption of an interaction with its negative regulator, MDM2. Subsequent phosphorylation and acetylation of p53 promote different interactions with other proteins and with target gene regulatory elements to facilitate cell-cycle arrest, apoptosis, or adaptation in response to DNA damage. Downstream of p53, p21 is responsible for growth arrest in G1, but other p53 target genes are responsible for G2 cell-cycle arrest. In response to genotoxic insult, p53-induced apoptosis results from overlapping downstream pathways that both suppress mitogenic and survival signaling and promote pro-apoptotic signaling. Adaptation to DNA damage is manifested by p53-mediated expression of its negative regulator, MDM2. The frequency of observed mutations in p53 predicts that its inactivation is a requisite step in tumorigenesis, as p53 is mutated in approximately 50% of human tumors. Thus, it is likely that in the remaining tumors, genetic aberrations will occur in pathways that regulate p53 or in pathways directly downstream of p53. The advances in the understanding of p53 signaling over the past few years point to many potential overlapping signaling pathways, where mutations may occur as alternative modes to p53 mutation.
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PMID:Regulation of p53 stability and activity in response to genotoxic stress. 1076 29

KILLER/DR5, a tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) death receptor gene, has been shown to be induced by DNA damaging agents and radiation in a p53-dependent manner. Although TRAIL is a potential therapeutic agent for cancer, the induction mechanism of its receptors is poorly understood. Here we show the identification of three p53 DNA-binding sites in the KILLER/DR5 genomic locus located upstream (BS1; -0.82 Kb) of the ATG site, within Intron 1 (BS2; +0.25 Kb downstream of the ATG) and within Intron 2 (BS3; +1.25 Kb downstream of the ATG). A modified p53-binding and immunoselection protocol using a wild-type p53-expressing adenovirus vector (Ad-p53) was used to identify the binding sites and to show that each binding site can bind specifically to wild-type p53 protein (wt-p53). A reporter assay revealed that only BS2 could enhance luciferase expression driven by a basal promoter. We constructed a reporter plasmid carrying the genomic regulatory region of KILLER/DR5 including the three p53 DNA-binding sites but no additional basal promoter. The genomic fragment showed basal transcriptional activity which was induced by wt-p53 but not by mutant p53, and human papilloma virus E6 inhibited the p53-dependent activation. Mutation of BS2 abrogated not only the binding activity of wt-p53 but also the induction of the KILLER/DR5 genomic promoter-reporter gene, indicating that BS2 is responsible for the p53-dependent transactivation of KILLER/ DR5. In p53-wild-type but not -mutant or -null cell lines, doxorubicin treatment stabilized p53 protein, and increased specific binding to BS2 as revealed by EMSA, and upregulated the KILLER/DR5 promoter-luciferase reporter gene. These results suggest that the transactivation of KILLER/DR5 is directly regulated by exogenous or endogenous wt-p53 and establishes KILLER/DR5 as a p53 target gene that can signal apoptotic death.
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PMID:Wild-type p53 transactivates the KILLER/DR5 gene through an intronic sequence-specific DNA-binding site. 1077 7

Cells respond to genotoxic stress by activation of many genes, including the tumor suppressor p53. p53 activates transcriptionally target genes, such as p21waf1 and gadd45, which can lead to cell cycle arrest, or bax, which can lead to cell death. We examined the response to genotoxic stress in two hematopoietic cell lines that harbor either wild-type (MOLT-4) or a mutant p53 with a codon 161 mutation (U266). We adapted a multiprobe RNase protection assay (RPA) to determine the steady-state RNA levels, and in combination with nuclear runoff assays, transcriptional rates of multiple stress-induced genes. We found a differential activation of growth arrest and cell death-specific p53 target genes in cells with wild-type or mutant p53. Our results show that genotoxic stress can activate the p21waf1 and gadd45 genes in both cell lines. However, the bax gene was not induced in U266 cells. Bax and gadd45 gene induction could be efficiently blocked by pretreating the cells with the antioxidant compound pyrrolidine dithiocarbamate, suggesting that oxidative stress was involved in these responses. Induction of all three genes in MOLT-4 cells was clearly at the transcriptional level, because we detected transcriptional activity by nuclear runoff RPA assays, and transfection with a consensus p53 binding sequence. U266 cells did not activate the same reporter, in spite of the upregulation of p21waf1 and gadd45 RNA levels. However, the p21waf1-reporter constructs containing 0.9 to 2.4 kb of the native p21 promoter were potently activated in U266 cells. These results indicate a differential regulation of p53 target genes in cells containing wild-type or codon 161 mutant p53.
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PMID:Differential upregulation of p53-responsive genes by genotoxic stress in hematopoietic cells containing wild-type and mutant p53. 1079 22

Polycyclic aromatic hydrocarbon carcinogens (PAHs) and their metabolites have been found to result in a rapid accumulation of p53 gene product in human and mouse cells. However, the induced p53 protein was reported to be transcriptionally inactive. In the present study, the induction of p53 target gene expression after the treatment with either benzo(a)pyrene (B[a]P) or 1-nitropyrene (1-NP) was investigated. A marked induction of messenger RNA (mRNA) expressions of Mdm2, Bax, and p21 was detected in wild-type p53-expressing cells after the treatment with either B[a]P or 1-NP, whereas no significant change in mRNA expression of these genes was observed in p53-negative and mutant cells. 1-NP activated the p21 promoter in a p53-dependent manner. Binding activity of p53 to a p53 consensus sequence increased after the treatment in wild-type p53-expressing cells. Nevertheless, the induced mRNA levels of the p21 did not result in a proportional p21 protein increase, indicating the possibility of post-transcriptional regulation of the protein. With the addition of MG-132, a proteasome inhibitor, to B[a]P or 1-NP treatments, both p21 and p53 protein levels were increased; however, the increase in p21 protein levels was significantly larger than the increase in p53 protein levels. PAHs treatment increased the level of ubiquitinated p21. These results suggest that the p21 product is degraded by the ubiquitin-proteasome system. We conclude that PAHs-induced p53 protein is transcriptionally active.
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PMID:Polycyclic aromatic hydrocarbon carcinogens increase ubiquitination of p21 protein after the stabilization of p53 and the expression of p21. 1083 73

Although p53 mutations in tumors typically result in loss of transactivation of p53 target genes some mutants display gain-of-function activity. The latter has important implications for the design of rational cancer therapy. We previously described a germ-line p53 mutation (deletion of codon 236, Y236delta) associated with a familial brain tumor syndrome. To determine whether this tissue-specific tumor predisposition reflects a gain-of-function activity of Y236delta or an effect of genetic background we have developed a mouse brain tumor model. Primary neuroectodermal cells deficient for p53 (+/- or -/-) and transduced with Y236delta using a retroviral vector were transplanted into the brain of adult wild-type mice. This neurografting paradigm circumvents the problem of early lethal tumors at extracerebral sites associated with germ-line p53 deficiency. Brain tumors arising in this mouse model were highly invasive, reflecting an important feature of the human disease. Tumors arose from p53+/- cells only when transduced with Y236delta. In keeping with in vitro data showing that Y236delta has dominant-negative activity, these tumors retained the endogenous wild-type p53 allele but accumulated high levels of Y236delta. However, the presence of Y236delta in transplanted p53-/- cells had no effect on the tumor frequency, 15% versus 27% without the mutant. In conclusion, Y236delta is transdominant but exerts no gain-of-function activity mediating a more penetrant tumor phenotype.
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PMID:p53 transdominance but no gain of function in mouse brain tumor model. 1085 Apr 51

p53, a tumor suppressor, inhibits cell proliferation by inducing cellular genes involved in the regulation of the cell cycle. MCG10, a novel cellular p53 target gene, was identified in a cDNA subtraction assay with mRNA isolated from a p53-producing cell line. MCG10 can be induced by wild-type but not mutant p53 and by DNA damage via two potential p53-responsive elements in the promoter of the MCG10 gene. The MCG10 gene contains 10 exons and is located at chromosome 3p21, a region highly susceptible to aberrant chromosomal rearrangements and deletions in human neoplasia. The MCG10 gene locus encodes at least two alternatively spliced transcripts, MCG10 and MCG10as. The MCG10 and MCG10as proteins contain two domains homologous to the heterogeneous nuclear ribonucleoprotein K homology (KH) domain. By generating cell lines that inducibly express either wild-type or mutated forms of MCG10 and MCG10as, we found that MCG10 and MCG10as can suppress cell proliferation by inducing apoptosis and cell cycle arrest in G(2)-M. In addition, we found that MCG10 and MCG10as, through their KH domains, can bind poly(C) and that their RNA-binding activity is necessary for inducing apoptosis and cell cycle arrest. Furthermore, we found that the level of the poly(C) binding MCG10 protein is increased in cells treated with the DNA-damaging agent camptothecin in a p53-dependent manner. These results suggest that the MCG10 RNA-binding protein is a potential mediator of p53 tumor suppression.
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PMID:MCG10, a novel p53 target gene that encodes a KH domain RNA-binding protein, is capable of inducing apoptosis and cell cycle arrest in G(2)-M. 1089 98

It is now well accepted that the p53 C-terminus plays a central role in controlling the activity of the wild-type molecule. In our previous studies, we observed that a C-terminally altered p53 protein (p53AS), generated by an alternative spliced p53 mRNA, induces an attenuated p53-dependent apoptosis, compared to that induced by the regularly spliced form (p53RS). In the present study we analysed the interrelationships between these two physiological variants of wild-type p53, and found that in cells co-expressing both forms, in contrast to the expected additive effect on the induction of apoptosis, p53AS inhibits apoptosis induced by p53RS. This inhibitory effect is specific for p53-dependent apoptosis and was not evident in a p53-independent apoptotic pathway induced by growth factor deprivation. Furthermore, the expression of p53AS in transiently transfected cells caused both inhibition of apoptosis and inhibition of the p53RS-dependent transactivation of a number of p53 target genes. These results suggest that expression of an alternatively spliced p53 form may serve as an additional level in controlling the complexity of p53 function by the C-terminal domain.
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PMID:p53-dependent apoptosis is regulated by a C-terminally alternatively spliced form of murine p53. 1091 96

The cell surface decoy receptor proteins TRID (also known as DcR1 or TRAIL-R3) and TRUNDD (DcR2, TRAIL-R4) inhibit caspase-dependent cell death induced by the cytotoxic ligand TRAIL in part because of their absent or truncated cytoplasmic death domains, respectively. We previously identified the death domain containing proapoptotic TRAIL death receptor KILLER/DR5 (TRAIL-R2) as an upregulated transcript following exposure of cancer cells, with wild-type but not with mutant or degraded p53 proteins, to a cytotoxic dose of adriamycin. In the present studies we provide evidence that expression of the TRAIL decoy receptors TRUNDD and TRID increases following infection of cancer cells with p53-expressing adenovirus (Ad-p53), in a manner similar to other p53 target genes such as KILLER/DR5 and p21WAF1/CIP1. Subsequent overexpression of TRUNDD in colon cancer cell lines caused a significant delay in killing induced by TRAIL. Furthermore, cotransfection of TRUNDD with either p53 or KILLER/DR5 (at a 4:1 DNA ratio) in colon cancer cells decreased cell death caused by either gene. This protective effect of TRUNDD was not dependent on the presence of TRAIL, and overexpression of TRUNDD did not alter the protein levels of either p53 or KILLER/ DR5. Further deletion studies showed that whereas protection by TRUNDD against TRAIL-mediated apoptosis did not require an intact intracellular domain (ICD), the first 43 amino acids of the ICD of TRUNDD were needed for protection against cell death induced by p53 or KILLER/DR5. Our results suggest a model in which the TRAIL decoy receptors may be induced by p53, thereby attenuating an apoptotic response that appears to involve KILLER/DR5. Therefore, the p53-dependent induction of TRUNDD may provide a mechanism to transiently favor cell survival over cell death, and overexpression of TRUNDD may be another mechanism of escape from p53-mediated apoptosis in gene therapy experiments.
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PMID:The TRAIL decoy receptor TRUNDD (DcR2, TRAIL-R4) is induced by adenovirus-p53 overexpression and can delay TRAIL-, p53-, and KILLER/DR5-dependent colon cancer apoptosis. 1093 23

Many p53-inducible genes have been identified that might play a role in mediating the various downstream activities of p53. We have identified a close relative of ribonucleotide reductase, recently named p53R2, as a p53-inducible gene, and show that this gene is activated by several stress signals that activate a p53 response, including DNA damaging agents and p14(ARF). p53R2 expression was induced by p53 mutants that are defective for the activation of apoptosis, but retain cell cycle arrest function, although no induction of p53R2 was seen in response to p21(WAF1/CIP1)-mediated cell cycle arrest. Several isoforms of the p53 family member p73 were also shown to induce p53R2 expression. Transient ectopic expression of either wild type p53R2 or p53R2 targeted to the nucleus, did not significantly alter cell cycle progression in unstressed cells. The identification of this gene as a p53 target supports a direct role for p53 in DNA repair, in addition to inhibition of growth of damaged cells. Oncogene (2000) 19, 4283 - 4289
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PMID:A ribonucleotide reductase gene is a transcriptional target of p53 and p73. 1098 Jun 2

P53 plays a critical role in G1 checkpoint after DNA damage. MDM2 gene is a p53 target gene and its protein forms a feedback loop with p53 and inhibits p53-mediated G1 arrest. Sterigmatocystin (ST) is a mycotoxin and carcinogen. In this study we show that exposure of cells to ST for 12 or 24 h resulted in failure of G1 arrest at both time points. Accordingly, p53 protein was not increased and p21WAF1 expression was inhibited at 12 h, and both proteins were weakly induced at 24 h after treatment with ST. Meanwhile, MDM2 protein was induced in a p53-dependent fashion by ST at both 12 and 24 h. The induction of MDM2 was coincident with the cellular responses of p53 and p21WAF1, and might contribute to the failure of G1 arrest in ST-treated cells. In addition, ST-treated cells exhibited G2M arrest, regardless of p53 status. Our results indicate that the carcinogenic effects of ST seem to be mediated by failure of p53-mediated G1 checkpoint.
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PMID:Absence of p53-mediated G1 arrest with induction of MDM2 in sterigmatocystin-treated cells. 1099 85

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