Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P51532 (transcriptional activator)
 6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Some mutant forms of the p53 protein have been shown to gain new functions that are not shared by the wild-type p53 protein; (1) mutant p53 proteins can transcriptionally transactivate the multi-drug resistance gene-1 (MDR-1) and (2) when expressed in non-tumorigenic cells with no endogenous p53 protein, mutant p53 proteins can enhance the tumorigenic potential of these cells (Dittmer et al., 1993). It has recently been shown (Lin et al., 1994b) that the transcriptional activator domain of the p53 protein contains two amino acids, leu-22 and trp-23, which are required by the wild-type p53 protein for transcriptional activity. To determine whether these same amino acid residues are utilized by mutant p53 proteins for their gain of function phenotype, the triple mutant p53 protein (at residues 22 and 23 in the transactivation domain and residue 281 in the DNA binding domain--a gain of function mutant) was made. While the p53-281 mutant transcriptionally activates the MDR-1 gene and enhances the tumorigenic potential of cells it is expressed in, the 22, 23, 281 triple mutant failed to carry out either of these functions.
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PMID:Two critical hydrophobic amino acids in the N-terminal domain of the p53 protein are required for the gain of function phenotypes of human p53 mutants. 778 87

The p53 tumor suppressor gene product, a sequence-specific DNA-binding protein, has been shown to act as a transcriptional activator and repressor both in vitro and in vivo. Consistent with its role in regulating transcription are recent observations that the N-terminal acidic domain of p53 binds directly to the TATA box-binding protein subunit of the general transcription factor, TF IID. It is now demonstrated that wild-type p53 (wt-p53) inhibits human immunodeficiency virus type 1 (HIV-1) long terminal repeat (LTR)-directed chloramphenicol acetyltransferase activity in a cotransfection assay system. Importantly, this effect of wt-p53 on the HIV-1 LTR was also demonstrated by in vitro transcription assays. In addition, the Sp1 sites and the TATA box of the HIV-1 LTR are demonstrated to be the primary sites involved with p53-induced effects on this viral promoter. The upstream elements of the HIV-1 LTR, including the nuclear factor kappa B (NF-kappa B) binding sites, decrease the p53-induced inhibitory effects on viral transcription. In the presence of the HIV-1 TAR sequence and Tat protein, the HIV-1 LTR also becomes less sensitive to wt-p53-induced inhibition. By using a retroviral vector delivery system, mutant forms of p53 genes were expressed in two HIV-1 latently infected cell lines, ACH-2 and U1. In the ACH-2 cell line, which is now demonstrated to contain an endogenous mutant form of p53 (amino acid 248, Arg to Gln), additional mutant p53 proteins did not alter HIV-1 replication. In U1 cells, which completely lack endogenous p53, overexpression of mutant p53 led to an increase in HIV-1 replication. Thus, these data indicate a possible functional role for wt-p53 and mutant p53 proteins in the control of HIV-1 replication patterns and proviral latency.
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PMID:The tumor suppressor protein p53 strongly alters human immunodeficiency virus type 1 replication. 820 5

Cells with divergent mutant alleles of the p53 gene have different biological and biochemical properties in vitro. Increasing evidence indicates that p53 is a transcriptional activator, and recently, high affinity DNA binding sites for p53 have been identified. The purpose of this study was to determine in vivo, the effect that various mutant p53 proteins have on their ability to mediate transactivation and to bind specifically to DNA. Either a p53 responsive or control reporter gene was transfected into 18 human carcinoma cell lines, having various p53 mutations, either with or without a wild-type p53 expression vector. The CAT activity and DNA gel retardation were studied to measure transactivation and DNA binding by these endogenous p53s. As expected, the endogenously produced wild-type p53 binds to DNA binding sequences and can transactivate a reporter construct containing a p53 high affinity DNA binding site. Four of five cell lines with homozygous p53 mutations at codon 273 (273His), contained p53 which had the ability to bind to p53 DNA binding sequences and transactivate. In contrast, all the homozygous, non-codon 273 mutant p53s (156Pro, 175His, 223Leu, 248Gln, 248Trp, 280Lys) present in the other cell lines had no transactivating ability. These findings suggest that the biology of cancers with mutations at codon 273 may be different than those with p53 mutations at other sites. The p53 from WRO, a thyroid carcinoma cell line with p53 mutation at codon 223 (223Leu), was able to bind p53 DNA recognition sequences, but was unable to transactivate. Interestingly, in a vulvar carcinoma cell line (A431) with a p53 mutation at codon 273 (273His), the p53 was unable to transactivate and gave an aberrant band on gel retardation. Both CEM and SK-UT-1, which have compound heterozygous mutations at codons 175/248 (175His/248His), produced p53 which can complex with DNA, as well as transactivate. In contrast, the p53 in cell lines with either homozygous 175His or 248His p53 mutations, were unable either to transactivate or bind to the p53 response element. A cell line (NPA) heterozygous for 266Glu p53 mutation, was able to efficiently transactivate a reporter containing a p53 DNA binding site, therefore showing no evidence of a dominant negative effect of the endogenous p53 mutant allele. In summary, this in vivo study further supports the idea that different p53 mutant alleles have various properties which may affect their function.
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PMID:Transactivational and DNA binding abilities of endogenous p53 in p53 mutant cell lines. 820 36

We used a yeast-based genetic assay, the two-hybrid system, to characterize the domain of the tumor-suppressor p53 involved in oligomerization. This assay relies on the reconstitution of the function of a transcriptional activator, the yeast GAL4 protein, via the interaction of a protein fused to the DNA-binding domain of GAL4 with a protein fused to the transcriptional activation domain of GAL4. We show by a reconstruction experiment that this approach could detect the interaction of p53 deleted for its N-terminal activation domain with SV40 large T antigen. We then searched a library of human proteins present as activation domain hybrids for proteins that can interact with the hybrid of p53 with the DNA-binding domain. This search identified 36 plasmids containing the p53 gene, representing 10 different classes. These results provide an additional in vivo demonstration of p53 oligomerization. The smallest p53 fragment identified from screening the library contained only amino acids 331-393, indicating that this small C-terminal fragment is sufficient to mediate oligomerization. In addition, a mutant p53 protein could bind to the wild-type protein in this assay, providing support for the idea that mutant forms of p53 act in a dominant-negative manner through C-terminal oligomerization with the wild type.
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PMID:Use of the two-hybrid system to identify the domain of p53 involved in oligomerization. 850 89

p53 is a nuclear phosphoprotein whose function is classified as tumor suppression. Studies have shown that p53 functions by binding to p53 DNA recognition sequences and regulates transcription of growth-regulatory genes. Various p53 recognition sequences have recently been identified. pOST2 contained two copies of a palindromic high-affinity DNA-binding sequence for p53; the other p53 recognition sequences included p53-binding fragments found in the human ribosomal gene cluster (pRGC) region and in the murine muscle creatine kinase promoter (pMCK). The purpose of this study was to compare the abilities of various p53 recognition sequences to mediate transcription in the presence of endogenously produced wild-type (wt) or mutant p53. Three p53-responsive chloramphenicol acetyltransferase (CAT) reporter constructs (pOST2, pRGC, and pMCK) that contain one or two copies of p53 recognition sequences upstream of a herpes thymidine kinase (TK) promoter and CAT reporter cDNA were constructed. Either a p53-responsive gene or a control reporter gene was transfected into human carcinoma cell lines (having various p53 mutations) either with or without a wt or mutant p53 expression vector. CAT activity was assayed to measure transactivation through the various p53-responsive elements. We showed that pOST2 had a greater ability to mediate transactivation by p53 than either pRGC or pMCK. p53 with a mutation at either codon 175 or 248 was unable to transactivate a reporter gene with pOST2, pRGC, or pMCK. We found it interesting that pOST2, but not pRGC or pMCK, was able to mediate transactivation in cell lines that produce codon 273-mutant p53. These findings suggest that various sensitivities of the different p53-responsive elements to specific mutant and wt p53s may be an important factor in the role of p53 as a transcriptional activator both under normal physiological conditions and during carcinogenesis.
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PMID:p53 transactivation through various p53-responsive elements. 864 24

The transcriptional activator p53 is known to interact with components of the general transcription factor TFIID in vitro. To examine the relevance of these associations to transcriptional activation in vivo, plasmids expressing a p53-GAL4 chimera and Drosophila TATA-binding protein (dTBP) were transfected into Drosophila Schneider cells. p53-GAL4 and dTBP displayed a markedly synergistic effect on activated transcription from a GAL4 site-containing reporter that was at least 10-fold greater than observed with other activators tested. A mutant p53 previously shown to be defective in both transcriptional activation in vivo and in binding to TBP-associated factors (TAFs) in vitro, although still capable of binding dTBP, did not cooperate with dTBP, suggesting that TAFs may contribute to this synergy. Providing further support for this possibility, transfected dTBP assembled into rapidly sedimenting complexes and could be immunoprecipitated with anti-TAF antibodies. While overexpression of any of several TAFs did not affect basal transcription, in either the presence or the absence of cotransfected dTBP, overexpression of TAFII230 inhibited transcriptional activation mediated by p53-GAL4 as well as by GAL4-VP16 and Sp1. Overexpression of TAFII40 and TAFII60 also inhibited activation by p53-GAL4 but had negligible effects on activation by GAL4-VP16 and Sp1, while TAFII110 did not affect any of the activators. TAF-mediated inhibition of activated transcription could be rescued by high levels of exogenous dTBP, which also restored full synergy. These data demonstrate for the first time that functional interactions can occur in vivo between TBP, TAFs, and p53.
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PMID:Functional interaction between p53, the TATA-binding protein (TBP), andTBP-associated factors in vivo. 875 30

In addition to serving a role as a DNA binding-dependent transcriptional activator, p53 has been reported to repress a variety of promoters that lack p53 binding sites. Data from recent studies have suggested that this activity is mediated via an interaction between p53 and the TATA box binding protein (TBP). To investigate the functional relevance of this interaction in vivo, we have performed transient transfection assays in Drosophila Schneider cells. Wild-type p53 was found to repress expression from TATA box- but not initiator (Inr)-containing promoters activated by GAL4-VP16, GAL4-ftzQ or Sp1. A mutant p53(His175), defective in DNA binding and transcriptional activation, also inhibited TATA-dependent transcription activated by Sp1. However, p53 was unable to repress a basal TATA promoter stimulated by overexpression of TBP. Furthermore, overexpression of TBP failed to rescue the p53-mediated repression of activated transcription and a p53 mutant with its N-terminal TBP interaction domain intact, but defective in transcriptional activation and binding to TBP-associated factors (TAFs), was similarly defective in transcriptional repression. These data suggest that a p53-TBP interaction is not sufficient for transcriptional repression by p53 and that repression involves an interaction between p53 and other factors, such as TAFs, that are required for activated but not basal transcription. We suggest that p53-mediated repression results from squelching of a factor limiting for activated transcription from TATA- but not Inr-containing promoters.
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PMID:Transcriptional repression by p53 involves molecular interactions distinct from those with the TATA box binding protein. 893 84

The tumor suppressor protein p53 acts as a transcriptional activator that can mediate cellular responses to DNA damage by inducing apoptosis and cell cycle arrest. p53 is a nuclear phosphoprotein, and phosphorylation has been proposed to be a means by which the activity of p53 is regulated. The cyclin-dependent kinase (CDK)-activating kinase (CAK) was originally identified as a cellular kinase required for the activation of a CDK-cyclin complex, and CAK is comprised of three subunits: CDK7, cyclin H, and p36MAT1. CAK is part of the transcription factor IIH multiprotein complex, which is required for RNA polymerase II transcription and nucleotide excision repair. Because of the similarities between p53 and CAK in their involvement in the cell cycle, transcription, and repair, we investigated whether p53 could act as a substrate for phosphorylation by CAK. While CDK7-cyclin H is sufficient for phosphorylation of CDK2, we show that p36MAT1 is required for efficient phosphorylation of p53 by CDK7-cyclin H, suggesting that p36MAT1 can act as a substrate specificity-determining factor for CDK7-cyclin H. We have mapped a major site of phosphorylation by CAK to Ser-33 of p53 and have demonstrated as well that p53 is phosphorylated at this site in vivo. Both wild-type and tumor-derived mutant p53 proteins are efficiently phosphorylated by CAK. Furthermore, we show that p36 and p53 can interact both in vitro and in vivo. These studies reveal a potential mechanism for coupling the regulation of p53 with DNA repair and the basal transcriptional machinery.
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PMID:p53 is phosphorylated by CDK7-cyclin H in a p36MAT1-dependent manner. 937 54

The p53 tumor suppressor protein, found mutated in over 50% of all human tumors, is a sequence-specific transcriptional activator. Recent studies have identified a p53 relative, termed p73. We were interested in determining the relative abilities of wild-type and mutant forms of p53 and p73alpha and -beta isoforms to transactivate various p53-responsive promoters. We show that both p73alpha and p73beta activate the transcription of reporters containing a number of p53-responsive promoters in the p53-null cell line H1299. However, a number of significant differences were observed between p53 and p73 and even between p73alpha and p73beta. Additionally, a Saccharomyces cerevisiae-based reporter assay revealed a broad array of transcriptional transactivation abilities by both p73 isoforms at 37 degreesC. Recent data have shown that p73 can associate with p53 by the yeast two-hybrid assay. When we examined complex formation in transfected mammalian cells, we found that p73alpha coprecipitates with mutant but not wild-type p53. Since many tumor-derived p53 mutants are capable of inhibiting transactivation by wild-type p53, we tested the effects of two representative hot-spot mutants (R175H and R248W) on p73. By cotransfecting p73alpha along with either p53 mutant and a p53-responsive reporter, we found that both R175H and R248W reduces the transcriptional activity of p73alpha. This decrease in transcriptional activity is correlated with the reduced ability of p73alpha to promote apoptosis in the presence of tumor-derived p53 mutants. Our data suggest the possibility that in some tumor cells, an outcome of the expression of mutant p53 protein may be to interfere with the endogenous p73 protein.
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PMID:p73 function is inhibited by tumor-derived p53 mutants in mammalian cells. 989 Oct 77

Human MDM2 (hMDM2) inhibits transcriptional activation mediated by wild-type p53 and its tumor-derived mutants. We present evidence to show that hMDM2 interacts with the tumor-derived mutants of p53 and inhibits transcriptional activation of the human c-myc promoter mediated by the tumor-derived mutants of p53 through two domains. These two domains of hMDM2 are able to function independent of each other. Interaction with either of the domains is sufficient for inhibition of mutant p53-mediated transactivation. One of these domains is the same as the wild-type p53 interaction domain of hMDM2, whereas a second domain is situated within amino acid 190 and 276 residues and is specific for mutant p53. hMDM2 does not inhibit transcriptional activation mediated by the transcriptional activator VP16, suggesting that the inhibition is not mediated by inactivation of a general transcription factor. The transactivation and the oligomerization domains of mutant p53 are dispensable for its interaction with hMDM2. Thus, both hMDM2 and p53 recognize each other through unique domains. These observations suggest that forms of hMDM2 incapable of interacting with the wild-type p53, and are often expressed in transformed cells, would inhibit mutant p53-mediated transactivation and antagonize the tumorigenic function of mutant p53. This inhibitory function of hMDM2 may account for infrequent co-occurrence of p53 mutation and hMDM2 overexpression in cancer cells. Our results also suggest distinct mechanisms for wild-type and mutant p53-mediated transcriptional activation.
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PMID:The human oncoprotein MDM2 uses distinct strategies to inhibit transcriptional activation mediated by the wild-type p53 and its tumor-derived mutants. 1117 71


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