UNIPROT:P20226 - FACTA Search

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Query: UNIPROT:P20226 (TATA-binding protein)
1,297 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

p53 activates transcription of genes with a p53 response element, and it can repress genes lacking the element. Here we demonstrate that wild-type but not mutant p53 inhibits transcription in a HeLa nuclear extract from minimal promoters. Wild-type but not mutant p53 binds to human TATA-binding protein (TBP). p53 does not bind to yeast TBP, and it cannot inhibit transcription in a HeLa extract where yeast TBP substitutes for human TBP. These results suggest a model in which p53 binds to TBP and interferes with transcriptional initiation.
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PMID:Wild-type p53 binds to the TATA-binding protein and represses transcription. 146 35

There is now much evidence to suggest that the p53 tumour suppressor protein functions to monitor the integrity of the genome. When DNA damage is detected, p53 suppresses cell growth to allow repair or directs the cell into apoptosis. The mechanism of action of p53 is as yet unclear but recent evidence has accumulated to suggest that p53 might act by regulating gene expression. Consistent with this model, p53 can both activate and repress a number of viral and cellular promoters. p53 has also been shown to bind to the CCAAT-binding Factor and TATA-binding protein (TBP), and there is direct evidence that p53 represses in vitro transcription by preventing TBP from binding DNA. We now provide evidence that p53 can repress transcription from the SV40 promoter by disrupting DNA/protein complexes involving transcription factor Sp1.
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PMID:p53 represses SV40 transcription by preventing formation of transcription complexes. 747 50

The expression of the 7B2 protein, secreted from a variety of neural and endocrine tissues, increases dramatically in specific neuroendocrine tumors. We have recently shown that human 7B2 can act as a molecular chaperone in the deaggregation of proteins in vitro. In order to identify polypeptides which might bind 7B2 in vivo, the yeast two-hybrid system was employed. Surprisingly, mere covalent linkage of 7B2 to the DNA-binding domains of two yeast transcription activators, Ace1 and Gal4, activates transcription from the ACE1 and GAL4 operon. 7B2's ability to activate nuclear transcription surpasses that of Ace1 and compares favourably with the strong activation domain of the tumor suppressor protein, p53. Our results suggest that 7B2 must possess an activating sequence, a domain which defines all transcriptional activator proteins. Like the acidic activation domains of some transcriptional activators, 7B2 also binds the yeast TATA-box binding protein, an essential polypeptide in the basic transcription machinery. Deletion analysis of the gene encoding 7B2 reveals two independent transcriptional activating sequences in the 185 amino acid protein. It is therefore conceivable that 7B2 not only has a functional role in the secretory pathway but also in the nucleus. Moreover, these findings raise an intriguing question regarding the activation domains of 7B2 and their possible link to 7B2's oncogenic potential.
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PMID:The neuroendocrine protein 7B2 contains unusually potent transcriptional activating sequences. 748 73

TATA-binding protein (TBP) gene promoter binding factor (TPBF) is a transactivator which binds to the TBP promoter element (TPE) sequence of the Acanthamoeba TBP gene promoter and stimulates transcription in vitro. We have isolated a cDNA clone encoding TPBF. TPBF is a polypeptide of 327 amino acids with a calculated molecular mass of 37 kDa. The predicted amino acid sequence of TPBF shows no significant homology to other proteins. TPBF has two potential coiled-coil regions, a basic region, a proline-rich region, a histidine-rich N terminus, and a nuclear targeting sequence. The recombinant protein has an apparent molecular mass of 50 kDa, identical with that of TPBF purified from Acanthamoeba. Recombinant TPBF is able to bind DNA and activate transcription with the same specificity as natural Acanthamoeba TPBF, demonstrating the authenticity of the clone. Mobility shift assays of co-translated TPBF polypeptides and chemical cross-linking demonstrate that TPBF is tetrameric in solution and when bound to DNA. Analyses of TPBF mutants show that Coiled-coil II is essential for DNA binding, but Coiled-coil I and the basic region are also involved. TPBF is thus a novel DNA-binding protein with functional similarity to the tumor suppressor protein p53.
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PMID:Cloning, expression, and characterization of the TATA-binding protein (TBP) promoter binding factor, a transcription activator of the Acanthamoeba TBP gene. 749 9

Tumor suppressor protein p53 is a potent transcriptional activator and regulates cell growth negatively. To characterize the transcriptional activation domain (TAD) of p53, various point mutants were constructed in the context of Gal4 DNA binding domain and tested for their transactivation ability. Our results demonstrated that the positionally conserved hydrophobic residues shared with herpes simplex virus VP16 and other transactivators are essential for transactivation. Also, the negatively charged residues and proline residues are necessary for full activity, but not essential for the activity of p53 TAD. Deletion analyses showed that p53 TAD can be divided into two subdomains, amino acids 1-40 and 43-73. An in vitro glutathione S-transferase pull-down assay establishes a linear correlation between p53 TAD-mediated transactivation in vivo and the binding activity of p53 TAD to TATA-binding protein (TBP) in vitro. Mutations that diminish the transactivation ability of Gal4-p53 TAD also impair the binding activity to TBP severely. Our results suggest that at least TBP is a direct target for p53 TAD and that the binding strength of TAD to TBP (TFIID) is an important parameter controlling activity of p53 TAD. In addition, circular dichroism spectroscopy has shown that p53 TAD peptide lacks any regular secondary structure in solution and that there is no significant difference between the spectra of the wild type TAD and that of the transactivation deficient mutant type.
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PMID:Transactivation ability of p53 transcriptional activation domain is directly related to the binding affinity to TATA-binding protein. 755 31

Murine tumor suppressor p53 is phosphorylated in the NH2-terminal transactivating domain at serines 9, 18, and 37. Change of any one of these serines to either alanine or aspartic acid did not alter p53 suppression of transformation of rat embryo fibroblasts by activated ras and E1A. Change of any two of these serines to alanines, however, led to a significant decrease in suppressor function. Substitution of alanines for all three serines caused the most severe loss of suppression and also reduced transactivation functions. The triple substitution had no apparent effects on intracellular accumulation or localization of p53, oligomerization, DNA binding, or interaction with the TFIID TATA-binding protein. In contrast, triple substitution of aspartic acid for serines 9, 18, and 37 had minimal effects on suppression and transactivation by p53. These results argue strongly that phosphorylation of serines 9, 18, and 37 facilitates the suppression and transactivation functions of p53.
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PMID:Serine phosphorylation in the NH2 terminus of p53 facilitates transactivation. 775 94

The tumor suppressor gene product p53 can activate and repress transcription. Both transcriptional activation and repression are thought to involve the direct interaction of p53 with the basal transcriptional machinery. Previous work has demonstrated an in vitro interaction between p53 and the TATA-binding protein that requires amino acids 20 to 57 of p53 and amino acids 220 to 271 of the TATA-binding protein. The present results show that a 75-amino-acid segment from the carboxy terminus of p53 also can bind to the TATA-binding protein in vitro, and this interaction requires amino acids 217 to 268 of the TATA-binding protein, essentially the same domain that is required for interaction with the amino-terminal domain of p53. A carboxy-terminal segment of p53 can mediate repression when bound to DNA as a GAL4-p53 fusion protein. The amino- and carboxy-terminal p53 interactions occur within the domain on the TATA-binding protein to which the adenovirus 13S E1A oncoprotein has previously been shown to bind. The 13S E1A oncoprotein can dissociate the complex formed between the carboxy-terminal domain of p53 and the TATA-binding protein and relieve p53-mediated transcriptional repression. These results demonstrate that two independent domains of p53 can potentially interact with the TATA-binding protein, and they define a mechanism--relief of repression--by which the 13S E1A oncoprotein can activate transcription through the TATA motif.
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PMID:Two domains of p53 interact with the TATA-binding protein, and the adenovirus 13S E1A protein disrupts the association, relieving p53-mediated transcriptional repression. 779 29

Hepatitis B virus is a major risk factor in human hepatocellular carcinomas. We have used protein affinity chromatography to show that the 17-kDa hepatitis B virus gene product, HBx, binds directly to the human tumor suppressor gene product, p53. Interaction of HBx with p53 did not prevent p53 from specifically binding DNA. Instead, HBx enhanced p53's oligomerization state on a DNA oligonucleotide containing a p53 response element. Optimal binding of HBx to p53 required intact p53, but weaker binding to both the N-terminal activation domain of p53 and a protein fragment containing the C-terminal DNA-binding and oligomerization domains of p53 was observed. In transient transfection experiments with human Calu-6 cells, HBx inhibited transactivation by p53 of a reporter gene containing a p53 response element. Also, HBx inhibited p53-stimulated transcription in vitro even when added to the reaction mixture after the formation of the preinitiation complex. Interaction of HBx with p53 did not prevent the activation domain of p53 from binding two general initiation factors, the TATA-box binding protein subunit of TFIID and the p62 subunit of TFIIH. To explain these results, we propose that localization of HBx to a promoter by interaction with DNA-bound p53 enables a repression domain in HBx to directly contact the basal transcription machinery and thereby repress transcription.
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PMID:Direct interaction of the hepatitis B virus HBx protein with p53 leads to inhibition by HBx of p53 response element-directed transactivation. 785 26

In this report we demonstrate that the cloned human TATA-binding protein (TBP) interacts with T antigen. TBP co-immunoprecipitates with T antigen when incubated with the T antigen-specific monoclonal antibody PAb419, and Protein-A agarose. Gel retention analysis with a radiolabeled TATA box-containing probe showed that the complex of TBP and T antigen can bind to the TATA box. Recently, p53 has also been shown to interact with TBP. Using TBP deletion mutants and co-immunoprecipitation experiments with p53 or T antigen, we show that both p53 and T antigen bind to the same region, amino acids 203-275, within the conserved C-terminal domain of TBP. Binding of p53 and T antigen to the same domain on TBP may lead to competition between the two proteins for transcriptional function.
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PMID:p53 and SV40 T antigen bind to the same region overlapping the conserved domain of the TATA-binding protein. 839 34

Earlier reports show that p53, both wild type and mutants, may affect transcription. Wild-type p53 activates promoters with p53-binding sites while inhibiting promoters without binding sites. Mutant p53, on the other hand, has been shown to activate transcription from specific promoters. These observations suggest that both wild-type and mutant p53 may interact with a general transcription factor(s). In this report, we have shown that the cloned TATA-binding protein (TBP) from human and yeast interacts with human p53. TBP co-immunoprecipitates with wild-type or mutant human p53 when incubated with the p53-specific monoclonal antibody and Protein A-agarose. Wild-type murine p53 has also been found to interact with human TBP. Protein blot assays have demonstrated that the interaction between p53 and human TBP is direct. By gel retention analysis, we have shown that the complex of TBP and p53 (both wild type and mutant) can bind to the TATA box. The similar qualitative binding capability of wild-type and mutant p53 with human TBP and the similarity of the two complexes in binding to the TATA box suggest that the functional discrimination between wild-type and mutant p53 may not lie in their ability to bind TBP. The nature of the p53.TBP or p53.TBP.TATA complex may determine the success of transcription.
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PMID:p53 binds to the TATA-binding protein-TATA complex. 851 46

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