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

The control of gene expression during development, differentiation and maintenance of cellular function is governed by a complex array of transcription factors. We have undertaken a molecular dissection of the regulatory factors that direct transcription of protein coding genes by RNA polymerase II. Our early studies identified sequence-specific transcriptional activators that bind to enhancer and promoter sequences to modulate the transcriptional initiation event. However, the mechanism by which activators enhance transcription and mediate promoter selectivity remained unknown. Combining biochemical purification and in vitro assays, we have recently identified an essential class of transcription factors called TAFs that are tightly associated with the basal factor TBP (TATA-binding protein). We have found that TAFs are responsible for at least two regulatory functions. Some TAFs serve as coactivators capable of binding activators and mediating enhancing function. Other TAFs have been shown to confer template selectivity by binding directly to core DNA elements of the promoter. Thus different subunits of TBP/TAF complexes perform a variety of functions critical for transcriptional regulation in animal cells.
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PMID:The biochemistry of transcription in eukaryotes: a paradigm for multisubunit regulatory complexes. 873 71

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

The crystal structure of a complex of human TATA-binding protein with TATA-sequence DNA has been solved, complementing earlier TBP/DNA analyses from Saccharomyces cerevisiae and Arabidopsis thaliana. Special insight into TATA box specificity is provided by considering the TBP/DNA complex, not as a protein molecule with bound DNA, but as a DNA duplex with a particularly large minor groove ligand. This point of view provides explanations for: (1) why T.A base-pairs are required rather than C.G; (2) why an alternation of T and A bases is needed; (3) how TBP recognizes the upstream and downstream ends of the TATA box in order to bind properly; and (4) why the second half of the TATA box can be more variable than the first.
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PMID:How proteins recognize the TATA box. 875 91

The gene encoding the TATA-binding protein, TBP, is highly overexpressed during the haploid stages of spermatogenesis in rodents. RNase protection analyses for mRNAs containing the previously identified first, second, and eighth exons suggested that most TBP mRNAs in testis did not initiate at the first exon used in somatic cells (here designated exon 1C). Using a sensitive ligation-mediated cDNA amplification method, 5' end variants of TBP mRNA were identified, and the corresponding cDNAs were cloned from liver and testis. In liver, a single promoter/first exon is used to generate a steady-state level of roughly five molecules of TBP mRNA per diploid cell equivalent. In testis, we detect modest up-regulation of the somatic promoter and recruitment of at least five other promoters. Three of the alternative promoter/first exons, including 1C and two of the testis-specific promoter/first exons, 1D and 1E, contribute roughly equivalent amounts of mRNA which, in sum, account for greater than 90% of all TBP mRNA in testis. As a result, round spermatids contain an estimated 1000 TBP mRNA molecules per haploid cell. Testis TBP mRNA also exhibits several low abundance 5' end splicing variants; however, all detected TBP mRNA leader sequences splice onto the common exon 2 and are expected to initiate translation at the same site within exon 2. The precise locations of the three major initiation exons are mapped on the gene. The identification of the strong testis-specific promoter/first exons will be important for understanding spermatid-specific tbp gene regulation.
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PMID:Spermatid-specific overexpression of the TATA-binding protein gene involves recruitment of two potent testis-specific promoters. 903 Jun 7

We have isolated and sequenced the cDNA encoding avian(chicken) TATA-binding protein (cTBP). The cTBP protein shows a significant homology to those of the other species, and especially its C-terminal region (180 amino acid residues) is identical to those of the vertebrates. By Northern blot analysis, we found that two transcripts with about 2.1 kb (cTBP0) and 2.7 kb (cTBP1) were expressed in various chicken tissues, though only one type of the TBP transcript was reported in vertebrates. A primer extension study demonstrated a single transcription start site. The analysis of the genomic structure of cTBP with the sequences of the two types of cTBP cDNAs(cTBP0 and cTBP1) revealed that the alternative polyadenylation generates two transcripts with different 3'untranslated regions (3'UTRs), indicating a putative role of the different 3'UTRs on the stability of cTBP mRNAs.
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PMID:Two forms of avian(chicken) TATA-binding protein mRNA generated by alternative polyadenylation. 917 84

Saccharomyces cerevisiae transcription factor IIIB (TFIIIB) is composed of three subunits: the TATA-binding protein, the TFIIB-related protein Brf, and B". TFIIIB, which is brought to RNA polymerase III-transcribed genes indirectly through interaction with DNA-bound TFIIIC or directly through DNA recognition by the TATA-binding protein, in turn recruits RNA polymerase III to the promoter. N-terminally deleted derivatives of Brf have been examined for their ability to interact with DNA-bound TFIIIC and with the other components of TFIIIB and for participation in transcription. Brf(165-596), lacking 164 N-proximal TFIIB-homologous amino acids, is competent to participate in the assembly of TFIIIB-DNA complexes and in TFIIIC-independent transcription. Even deletion of the entire TFIIB-homologous half of the protein, as in Brf(317-596) and Brf(352-596), allows some interaction with DNA-bound TBP and with the B" component of TFIIIB to be retained. The function of Brf(165-596) in transcription has also been examined in the context of B" with small internal deletions. The ability of Brf with this sizable N-terminal segment deleted to function in TFIIIC-independent transcription requires segments of B" that are individually indispensable although required on an either/or basis, in the context of complete Brf. These findings suggest a functional complementarity and reciprocity between the Brf and B" components of TFIIIB.
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PMID:Domains of the Brf component of RNA polymerase III transcription factor IIIB (TFIIIB): functions in assembly of TFIIIB-DNA complexes and recruitment of RNA polymerase to the promoter. 927 7

Drosophila heat shock factor (HSF) binds to specific sequence elements of heat shock genes and can activate their transcription 200-fold. Though HSF has an acidic activation domain, the mechanistic details of heat shock gene activation remain undefined. Here we report that HSF interacts directly with the general transcription factor TBP (TATA-box binding protein), and these two factors bind cooperatively to heat shock promoters. A third factor that binds heat shock promoters, GAGA factor, also interacts with HSF and further stabilizes HSF binding to heat shock elements (HSEs). The interaction of HSF and TBP is explored in some detail here and is shown to be mediated by residues in both the amino- and carboxyl-terminal portions of HSF. This HSF/TBP interaction can be specifically disrupted by competition with the potent acidic transcriptional activator VP16. We further show that the acidic domain of the largest subunit of Drosophila RNA polymerase II (Pol II) associates with TBP in vitro and is specifically displaced from TBP upon addition of HSF. The region of TBP that mediates both HSF and Pol II acidic domain binding maps to the conserved carboxyl-terminal repeats and depends on at least one of the TBP residues known to be contacted by VP16 and to be critical for transcription activation. We discuss these findings in the context of a model in which HSF triggers hsp70 transcription by freeing the hsp70 promoter-paused Pol II from the constraints on elongation caused by the affinity of Pol II for general transcription factors.
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PMID:Cooperative and competitive protein interactions at the hsp70 promoter. 940 12

The thyroid transcription factor 1 (TTF-1) is a tissue-specific transcription factor involved in the development of thyroid and lung. TTF-1 contains two transcriptional activation domains (N and C domain). The primary amino acid sequence of the N domain does not show any typical characteristic of known transcriptional activation domains. In aqueous solution the N domain exists in a random-coil conformation. The increase of the milieu hydrophobicity, by the addition of trifluoroethanol, induces a considerable gain of alpha-helical structure. Acidic transcriptional activation domains are largely unstructured in solution, but, under hydrophobic conditions, folding into alpha-helices or beta-strands can be induced. Therefore our data indicate that the inducibility of alpha-helix by hydrophobic conditions is a property not restricted to acidic domains. Co-transfections experiments indicate that the acidic domain of herpes simplex virus protein VP16 (VP16) and the TTF-1 N domain are interchangeable and that a chimaeric protein, which combines VP16 linked to the DNA-binding domain of TTF-1, undergoes the same regulatory constraints that operate for the wild-type TTF-1. In addition, we demonstrate that the TTF-1 N domain possesses two typical properties of acidic activation domains: TBP (TATA-binding protein) binding and ability to activate transcription in yeast. Accordingly, the TTF-1 N domain is able to squelch the activity of the p65 acidic domain. Altogether, these structural and functional data suggest that a non-acidic transcriptional activation domain (TTF-1 N domain) activates transcription by using molecular mechanisms similar to those used by acidic domains. TTF-1 N domain and acidic domains define a family of proteins whose common property is to activate transcription through the use of mechanisms largely conserved during evolutionary development.
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PMID:Structural and functional properties of the N transcriptional activation domain of thyroid transcription factor-1: similarities with the acidic activation domains. 942 25

Plasmid pYUK3 bearing the fet5+ gene of Schizosaccharomyces pombe was isolated from a genomic library of the fission yeast, and a detailed physical map of the whole genomic insert (ca. 9.6 Kbp) was constructed. The primary structure of the fet5+ gene and its flanking regions is established. The gene contains a single 45-bp intron in its distal part. A typical TATA-box (TATAAG) was found in the 5'-noncoding region ca. 50 bp upstream of the putative start of transcription, and the 3'-noncoding region contains AT-rich palindromes, which are probably involved in termination of the fet5+ transcription. A previously unidentified gene of Sz. pombe encoding a protein with some similarity to one of the transcriptional activators from the TBP (TATA-binding protein) group of SPT factors of transcription was found in the vicinity of the fet5+ gene. Taking into account that cDNA of the fet5(+)-gene was isolated as a suppressor of the genetic-defect of nuclear RNA polymerases I-III (Bioorg. Khim., 1997, vol. 23, No 3, pp. 234-237), this vicinity may be the first evidence of possible clustering, in the genome of the fission yeast, of genes participating in transcription regulation.
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PMID:[Exon-intron structure of the fet5+ gene of Schizosaccharomyces pombe and physical mapping of genome encompassing regions]. 955 Dec 1

Early region 1A (E1A) gene products of adenoviruses (Ad) play an essential role in both productive infection and cellular transformation. Besides their function to induce the expression of all other adenoviral genes they modulate the expression of specific cellular genes to ensure an efficient viral reproduction. Gene regulatory functions of E1A proteins are mainly located in the conserved regions 1-3 (CRs) and in the non-conserved amino terminal end and are mediated via protein/protein interactions with cellular factors. We could show recently, that the E1A N-terminus (amino acids [aa] 1-29) of oncogenic Ad12 contains a unique 'trans'-activation domain. Here we demonstrate that this region binds to rap30/TF(II)F and to the TATA-box binding protein TBP in vitro. Mutation analyses suggest that binding to rap30 and 'trans'-activation are two independent functions as a mutant which failed to interact with rap30 was still able to induce gene expression with wildtype efficiency. Moreover loss of transcriptional activity does not correlate with a loss of TBP binding suggesting that this association is not necessary for the N-terminal 'trans'-activating activity. Interestingly, aa 1-29 of Ad2 E1A binds also to rap30 indicating that this interaction might be a common feature of E1A proteins from different serotypes.
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PMID:Amino acids 1-29 of the adenovirus serotypes 12 and 2 E1A proteins interact with rap30 (TF(II)F) and TBP in vitro. 966 75

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