EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 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

A photo-cross-linking method has been used to map the subunits of Saccharomyces cerevisiae RNA polymerase (Pol) III with respect to DNA in binary (preinitiation) and ternary (RNA-elongating) transcription complexes. Transcription factor- and Pol III-containing complexes have been assembled on S. cerevisiae SUP4 tRNA(Tyr) gene probes containing the photoactive nucleotide 5-[N-(p-azidobenzoyl)-3-aminoallyl]-dUMP in different specified positions. Covalent DNA-protein linkages form upon irradiation of these complexes, and the Pol III subunits that are cross-linked to individual positions in the SUP4 tRNA gene have been identified. RNA Pol III cross-linking has been shown to require the box B downstream promoter element of the tRNA gene and the presence of transcription factor TFIIIB. Further proof of specificity has been provided by demonstrating that particular Pol III subunits move out of the range of upstream-placed photoactive nucleotides, and that others move into the range of downstream-placed photoactive nucleotides, as a consequence of initiating and elongating RNA chains. Binding and specific placement of Pol III have also been shown to require both the B' and the B" components of TFIIIB. Nine Pol III subunits are cross-linked from different positions of the SUP4 tRNA gene's nontranscribed strand. In binary transcription complexes, the two largest Pol III subunits are accessible to photo-cross-linking over the entire stretch of the DNase I footprint. The 27- and 34-kDa Pol III subunits are also relatively extended along DNA; its upstream projection makes the 34-kDa subunit a candidate for interaction with TFIIIB, while the 27-kDa subunit is accessible to photo-cross-linking from the leading edge of the Pol III binding site. Several subunits, including the 82- and 53-kDa subunits in binary transcription complexes, are relatively localized in their accessibility to cross-linking. Multiple Pol III subunits are accessible to specific cross-linking from a single photoactive nucleotide in the middle of the transcription bubble of an arrested ternary transcription complex. It is suggested that this precisely placed transcription complex comprises a dynamic ensemble of structural states rather than a single perfectly constrained entity.
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PMID:Orientation and topography of RNA polymerase III in transcription complexes. 842 14

Derivatives of the Saccharomyces cerevisiae SUP4 tRNATyr gene with binding sites for the transcription regulatory protein GCN4 located upstream of the transcriptional start site have been constructed. The effect of GCN4 on transcription of these genes by purified RNA polymerase III and transcription factors (TF) IIIB and IIIC has been analyzed. GCN4 effectively blocks initiation of transcription only when prebound to sites that overlap with the binding site of TFIIIB. Residual GCN4-repressed transcription is significantly redirected to nearby downstream sites, the selection of which depends on the location of bound GCN4. That prebound repressing GCN4 redirects, instead of merely blocking, the TFIIIC-dependent interaction of TFIIIB with DNA has been directly demonstrated by footprinting. The effect of GCN4 on transcription persists after it has been stripped off its DNA-binding site: once it has been redirected, DNA-bound TFIIIB remains in place, a consequence of the fact that it binds extraordinarily tightly to DNA without recognizing specific DNA sequence.
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PMID:Repression and redirection of Saccharomyces cerevisiae tRNA synthesis from upstream of the transcriptional start site. 842 36

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

The promoters of vertebrate and yeast U6 small nuclear RNA genes are structurally dissimilar, although both are recognized by RNA polymerase III. Vertebrate U6 RNA genes have exclusively upstream promoters, while the U6 RNA gene from the yeast Saccharomyces cerevisiae (SNR6) has internal and downstream promoter elements that match the tRNA gene intragenic A- and B-block elements, respectively. Substitution of the SNR6 A or B block greatly diminished U6 RNA accumulation in vivo, and a subcellular extract competent for RNA polymerase III transcription generated nearly identical DNase I protection patterns over the SNR6 downstream B block and a tRNA gene intragenic B block. We conclude that the SNR6 promoter is functionally similar to tRNA gene promoters, although the effects of extragenic deletion mutations suggest that the downstream location of the SNR6 B block imposes unique positional constraints on its function. Both vertebrate and yeast U6 RNA genes have an upstream TATA box element not normally found in tRNA genes. Substitution of the SNR6 TATA box altered the site of transcription initiation in vivo, while substitution of sequences further upstream had no effect on SNR6 transcription. We present a model for the SNR6 transcription complex that explains these results in terms of their effects on the binding of transcription initiation factor TFIIIB.
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PMID:Architecture of a yeast U6 RNA gene promoter. 847 59

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

We show that the high in vitro transcription efficiency of yeast RNA pol III is mainly due to rapid recycling. Kinetic analysis shows that RNA polymerase recycling on preassembled tDNA.TFIIIC.TFIIIB complexes is much faster than the initial transcription cycle. High efficiency of RNA pol III recycling is favored at high UTP concentrations and requires termination at the natural termination signal. Runoff transcription does not allow efficient recycling. The reinitiation process shows increased resistance to heparin as compared with the primary initiation cycle, as if RNA polymerase was not released after termination. Indeed, template competition assays show that RNA pol III is committed to reinitiate on the same gene. A model is proposed where the polymerase molecule is directly transferred from the termination site to the promoter.
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PMID:Facilitated recycling pathway for RNA polymerase III. 856 70

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