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

A system that detects the formation of complexes between different proteins by linking them to separate domains of the GAL4 transcription activator protein has been used to study protein-protein interactions between four essential and unique subunits of yeast RNA polymerase III (C82, C53, C34 and C31), the 70-kDa component of the initiation transcription factor IIIB (TFIIIB70) and the TATA-binding protein. We found that C82, C34, and C31 are able to combine with each other in vivo and that C34 interacts with TFIIIB70. These results suggest that C34 and TFIIIB70 are specificity determinants of the RNA polymerase III-TFIIIB interaction.
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PMID:Interaction between a complex of RNA polymerase III subunits and the 70-kDa component of transcription factor IIIB. 840 94

The U6 small nuclear (sn)RNA gene (SNR6) from the yeast Saccharomyces cerevisiae is transcribed by RNA polymerase III in vivo. This gene is unusual in having a TATA box at position -30, and an essential B-block element located downstream of the T-rich termination signal. The B block is one of the two intragenic promoter elements of transfer RNA genes that are recognized by transcription factor (TF)IIIC (ref. 4). But accurate in vitro transcription of yeast U6 snRNA gene by PolIII in a purified system requires only TFIIIB components, including the TATA-box binding protein TBP. Here we report that, after nucleosome reconstitution or chromatin assembly, U6 snRNA synthesis becomes dependent on TFIIIC and on the integrity of the B-block element. This observation resolves an apparent paradox between in vitro and in vivo results concerning the necessity of the downstream B-block element and sheds light on a new role of TFIIIC in gene activation.
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PMID:TFIIIC relieves repression of U6 snRNA transcription by chromatin. 846 80

Inactivation of the TATA-binding protein-containing complex TFIIIB contributes to the mitotic repression of RNA polymerase III transcription, both in frogs and in humans (J. M. Gottesfeld, V. J. Wolf, T. Dang, D. J. Forbes, and P. Hartl, Science 263:81-84, 1994; R. J. White, T. M. Gottlieb, C. S. Downes, and S. P. Jackson, Mol. Cell. Biol. 15:1983-1992, 1995). Using extracts of synchronized proliferating HeLa cells, we show that TFIIIB activity remains low during the early part of G1 phase and increases only gradually as cells approach S phase. As a result, the transcription of all class III genes tested is significantly less active in early G1 than it is in S or G2 phase, both in vitro and in vivo. The increased activity of TFIIIB as cells progress through interphase appears to be due to changes in the TATA-binding protein-associated components of this complex. The data suggest that TFIIIB is an important target for the cell cycle regulation of RNA polymerase III transcription during both mitosis and interphase of actively proliferating HeLa cells.
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PMID:Cell cycle regulation of RNA polymerase III transcription. 852 30

The hepatitis B virus X gene product transactivates a variety of cellular and viral genes. The mechanism for X induction of RNA polymerase (pol) III genes was investigated. By using Drosophila S-2 cells stably transformed with the X gene, the transient expression of a tRNA gene is enhanced. Comparing the transcriptional activities of extracts derived from these cells, all three types of RNA pol III promoters are stimulated by X. Interestingly, both S-2 and rat 1A cells stably transformed with the X gene produce increased cellular levels of the TATA-binding protein (TBP). By using various kinase inhibitors, it was found that the X-mediated increases in both transcription and TBP are dependent upon protein kinase C activation. Since TBP is a subunit of TFIIIB, the activity of this component fractionated from extracts derived from control and X-transformed cells was analyzed. These studies reveal that TFIIIB activity is substantially more limiting in control cells and that TFIIIB isolated from X-transformed cells has increased activity in reconstitution assays compared with TFIIIB isolated from control cells. Conversely, comparison of TFIIIC from control and X-transformed cell extracts revealed that there is relatively little change in its ability either to reconstitute transcription or to bind to DNA and that there is no change in the catalytic activity of RNA pol III. Studies were performed to determine whether directly increasing cellular TBP alone could enhance RNA pol III gene transcription. Transient expression of a TBP cDNA in rat 1A cells was capable of stimulating transcription activity from the resultant extracts in vitro. Together, these results demonstrate that one mechanism by which X mediates transactivation of RNA poll III genes is by increasing limiting TBP via the activation of cellular signaling pathways. The discovery that X increases cellular TBP, the universal transcription factor, provides a novel mechanism for the function of a viral transactivator protein and may explain the ability of X to produce such large and diverse effects on cellular gene expression.
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PMID:The hepatitis B virus X protein increases the cellular level of TATA-binding protein, which mediates transactivation of RNA polymerase III genes. 852 37

The proximal sequence element (PSE)-binding transcription factor (PTF) specifically recognizes the PSEs of both RNA polymerase II- and RNA polymerase III-transcribed small nuclear RNA (snRNA) genes. We previously have shown that PTF purified from human HeLa cells is a multisubunit complex of four polypeptides designated PTF alpha, -beta, -gamma, and -delta. We now report the isolation and expression of cDNAs encoding PTF gamma and PTF delta, as well as functional studies with cognate antibodies that recognize the native PTF complex in HeLa extracts. Immunoprecipitation studies confirm that the four PTF subunits originally found to copurify during conventional chromatography indeed form a tightly associated complex; they further show that the PTF so defined, including the gamma and delta subunits specifically, is essential for transcription of both class II and class III snRNA genes. Immunoprecipitation assays also show a weak substoichiometric association of the TATA-binding protein (TBP) with PTF, consistent with the previous report of a PTF-related complex (SNAPc) containing substoichiometric levels of TBP and a component (SNAPc43) identical in sequence to the PTF gamma reported here. Glutathione S-transferase pulldown assays further indicate relatively strong direct interactions of both recombinant PTF gamma and PTF delta with TBP, consistent either with the natural association of TBP with PTF in a semistable TBP-TBP-associated factor complex or with possible functional interactions between PSE-bound PTF and TATA-bound TBP during promoter activation. In addition, we show that in extracts depleted of TBP and TBP-associated factors, transcription from the U1 promoter is restored by recombinant TBP but not by TFIID or TFIIIB, indicating that transcription of class II snRNA genes requires a TBP complex different from the one used for mRNA-encoding genes.
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PMID:Cloning of two proximal sequence element-binding transcription factor subunits (gamma and delta) that are required for transcription of small nuclear RNA genes by RNA polymerases II and III and interact with the TATA-binding protein. 852 84

Transcription of the 45S rRNA genes is carried out by RNA polymerase I and at least two trans-acting factors, upstream binding factor (UBF) and SL-1. We have examined the hypothesis that SL-1 and UBF interact. Coimmunoprecipitation studies using an antibody to UBF demonstrated that TATA-binding protein, a subunit of SL-1, associates with UBF in the absence of DNA. Inclusion of the detergents sodium dodecyl sulfate and deoxycholate disrupted this interaction. In addition, partially purified UBF from rat cell nuclear extracts and partially purified SL-1 from human cells coimmunoprecipitated with the anti-UBF antibody after mixing, indicating that the UBF-SL-1 complex can re-form. Treatment of UBF-depleted extracts with the anti-UBF antibody depleted the extracts of SL-1 activity only if UBF was added to the extract prior to the immunodepletion reaction. Furthermore, SL-1 activity could be recovered in the immunoprecipitate. Interestingly, these immunoprecipitates did not contain RNA polymerase I, as a monospecific antibody to the 194-kDa subunit of RNA polymerase I failed to detect that subunit in the immunoprecipitates. Treatment of N1S1 cell extracts with the anti-UBF antibody depleted the extracts of SL-1 activity but not TFIIIB activity, suggesting that the binding of UBF to SL-1 is specific and not solely mediated by an interaction between UBF and TATA-binding protein, which is also a component of TFIIIB. These data provide evidence that UBF and SL-1 interact.
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PMID:The species-specific RNA polymerase I transcription factor SL-1 binds to upstream binding factor. 855 83

Saccharomyces cerevisiae transcription factor (TF) IIIB, a TATA-binding protein (TBP)-containing multisubunit factor, recruits RNA polymerase (Pol) III for multiple rounds of transcription. TFIIIC is an assembly factor for TFIIIB on TATA-less tRNA gene promoters. To investigate the role of TBP-DNA interactions in tRNA gene transcription, we generated sequence substitutions in the SUP4 tRNATyr gene TFIIIB binding site. Purified transcription proteins were used to analyze the selection of transcription initiation sites and the physical structures of the protein complexes formed on these mutant genes. We show that the association of TFIIIB with tRNA genes proceeds through an initial step of binding-site selection that is codirected by its TBP subunit and by TFIIIC. TFIIIB is assembled in a predominantly metric manner with regard to box A, the start site-proximal binding site of TFIIIC, but TFIIIC opens a window within which wild-type TBP can select the TFIIIB-binding site. Despite its clear preference for AT-rich sequences, TBP can mediate TFIIIB assembly at diverse DNA sequences, including stretches containing only G and C. However, a mutant TBP, m3, which recognizes TATAAA and TGTAAA and is active for Pol III transcription, utilizes other sequences only poorly. We also show that alternative alignments between DNA-bound TFIIIB and TFIIIC are possible, implying a remarkably flexible linkage, and suggest that Tfc4, the TFIIIB-assembling subunit of TFIIIC, could be responsible for such elasticity. The relevance of these findings to alternative initiation of Pol II- and other Pol III-transcribed genes is discussed.
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PMID:Alternative outcomes in assembly of promoter complexes: the roles of TBP and a flexible linker in placing TFIIIB on tRNA genes. 859 99

The yeast RNA polymerase III (pol III) general transcription factor TFIIIB is composed of three subunits; the TATA-binding protein (TBP)1, the TFIIB-related factor (BRF1), and a third factor termed TFIIIB90 or B". Here we report the purification of yeast TFIIIB90, cloning of the gene encoding TFIIIB90, and reconstitution of TFIIIB from recombinant polypeptides. The TFIIIB90 open reading frame encodes a 68-kDa polypeptide and has no obvious similarity to any other known protein sequences. The gene encoding TFIIIB90 is essential for viability of yeast. Using recombinant TFIIIB subunits, we found that TFIIIB90 interacts weakly with TBP in the absence of BRF1, and that this interaction is enhanced at least 25-fold by BRF1. In addition, TFIIIB90 showed pol III specificity as it could not interact with the pol II-specific TFIIB-TBP-DNA complex. To localize the regions of the TBP-DNA complex that interact with BRF1 and TFIIIB90, we tested whether the pol II factors TFIIA and TFIIB interfered with the binding of BRF1 and TFIIIB90 to TBP-DNA. Our results suggest that the binding sites for BRF1 and TFIIIB90 on TBP-DNA both overlap the binding sites for TFIIA and TFIIB.
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PMID:Cloning and functional characterization of the gene encoding the TFIIIB90 subunit of RNA polymerase III transcription factor TFIIIB. 866 56

The proximal sequence element (PSE)-binding transcription factor (PTF), which binds the PSE of both RNA polymerase II- and RNA polymerase III-transcribed mammalian small nuclear RNA (snRNA) genes, is essential for their transcription. We previously reported the purification of human PTF, a complex of four subunits, and the molecular cloning and characterization of PTF gamma and delta subunits. Here we describe the isolation and expression of a cDNA encoding PTF beta, as well as functional studies using anti-PTF beta antibodies. Native PTF beta, in either protein fractions or a PTF-Oct-1-DNA complex, can be recognized by polyclonal antibodies raised against recombinant PTF beta. Immunodepletion studies show that PTF beta is required for transcription of both classes of snRNA genes in vitro. In addition, immunoprecipitation analyses demonstrate that substantial and similar molar amounts of TATA-binding protein (TBP) and TFIIIB90 can weakly associate with PTF at low salt conditions, but this association is dramatically reduced at high salt concentrations. Along with our previous demonstration of both physical interactions between PTF gamma/PTF delta and TBP and the involvement of TFIIIB90 in the transcription of class III snRNA genes, these results are consistent with the notion that a TBP-containing complex related to TFIIIB is required for the transcription of class III snRNA genes, and acts through weak interaction with the four-subunit PTF.
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PMID:Cloning and characterization of the beta subunit of human proximal sequence element-binding transcription factor and its involvement in transcription of small nuclear RNA genes by RNA polymerases II and III. 881 54

Wild-type p53 represses Alu template activity in vitro and in vivo. However, upstream activating sequence elements from both the 7SL RNA gene and an Alu source gene relieve p53-mediated repression. p53 also represses the template activity of the U6 RNA gene both in vitro and in vivo but has no effect on in vitro transcription of genes encoding 5S RNA, 7SL RNA, adenovirus VAI RNA, and tRNA. The N-terminal activation domain of p53, which binds TATA-binding protein (TBP), is sufficient for repressing Alu transcription in vitro, and mutation of positions 22 and 23 in this region impairs p53-mediated repression of an Alu template both in vitro and in vivo. p53's N-terminal domain binds TFIIIB, presumably through its known interaction with TBP, and mutation of positions 22 and 23 interferes with TFIIIB binding. These results extend p53's transcriptional role to RNA polymerase III-directed templates and identify an additional level of Alu transcriptional regulation.
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PMID:p53 inhibits RNA polymerase III-directed transcription in a promoter-dependent manner. 894 63


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