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)

The mitotic state is associated with a generalized repression of transcription. We show that mitotic repression of RNA polymerase III transcription can be reproduced by using extracts of synchronized HeLa cells. We have used this system to investigate the molecular basis of transcriptional repression during mitosis. We find a specific decrease in the activity of the TATA-binding-protein (TBP)-containing complex TFIIIB. TBP itself is hyperphosphorylated at mitosis, but this does not appear to account for the loss of TFIIIB activity. Instead, one or more TBP-associated components appear to be regulated. The data suggest that changes in the activity of TBP-associated components contribute to the coordinate repression of gene expression that occurs at mitosis.
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PMID:Mitotic regulation of a TATA-binding-protein-containing complex. 789 93

The proximal sequence element (PSE), found in both RNA polymerase II (Pol II)- and RNA Pol III-transcribed small nuclear RNA (snRNA) genes, is specifically bound by the PSE-binding transcription factor (PTF). We have purified PTF to near homogeneity from HeLa cell extracts by using a combination of conventional and affinity chromatographic methods. Purified PTF is composed of four polypeptides with apparent molecular masses of 180, 55, 45, and 44 kDa. A combination of preparative electrophoretic mobility shift and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analyses has conclusively identified these four polypeptides as subunits of human PTF, while UV cross-linking experiments demonstrate that the largest subunit of PTF is in close contact with the PSE. The purified PTF activates transcription from promoters of both Pol II- and Pol III-transcribed snRNA genes in a PSE-dependent manner. In addition, we have investigated factor requirements in transcription of Pol III-dependent snRNA genes. We show that in extracts that have been depleted of TATA-binding protein (TBP) and associated factors, recombinant TBP restores transcription from U6 and 7SK promoters but not from the VAI promoter, whereas the highly purified TBP-TBP-associated factor complex TFIIIB restores transcription from the VAI but not the U6 or 7SK promoter. Furthermore, by complementation of heat-treated extracts lacking TFIIIC activity, we show that TFIIIC1 is required for transcription of both the 7SK and VAI genes, whereas TFIIIC2 is required only for transcription of the VAI gene. From these observations, we conclude (i) that PTF and TFIIIC2 function as gene-specific as gene-specific factors for PSE-and B-box-containing Pol III genes, respectively, (ii) that the form of TBP used by class III genes with upstream promoter elements differs from the from used by class III genes with internal promoters, and (iii) that TFIIIC1 is required for both internal and external Pol III promoters.
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PMID:Proximal sequence element-binding transcription factor (PTF) is a multisubunit complex required for transcription of both RNA polymerase II- and RNA polymerase III-dependent small nuclear RNA genes. 789 97

A yeast chimeric RNA polymerase III transcription system was constructed to explore the ordered, multistep process of gene activation in vivo. A promoter-deficient U6 RNA gene harboring GAL4-binding sites could be reactivated by fusing the GAL4 DNA-binding domain to components of the general transcription factor TFIIIC (tau) or TFIIIB. Expression of chimeric tau 138 or tau 131 (but not tau 95) subunits activated transcription from GAL4-binding sites located at various positions, including upstream of or within the gene. The function(s) of the B block binding domain of TFIIIC was provided by the fused GAL4-(1-147) domain. The GAL4-(1-147)-TFIIIB70 fusion protein acted at a distance like an activator of transcription. In contrast, none of the 10 different GAL4-(1-147)-polymerase subunit fusions was able to induce transcription, suggesting that RNA polymerase recruitment is not sufficient to initiate transcription.
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PMID:Directing transcription of an RNA polymerase III gene via GAL4 sites. 799 61

In Saccharomyces cerevisiae, two components of the RNA polymerase III (Pol III) general transcription factor TFIIIB are the TATA-binding protein (TBP) and the B-related factor (BRF), so called because its amino-terminal half is homologous to the Pol II transcription factor IIB (TFIIB). We have cloned BRF genes from the yeasts Kluyveromyces lactis and Candida albicans. Despite the large evolutionary distance between these species and S. cerevisiae, the BRF proteins are conserved highly. Although the homology is most pronounced in the amino-terminal half, conserved regions also exist in the carboxy-terminal half that is unique to BRF. By assaying for interactions between BRF and other Pol III transcription factors, we show that it is able to bind to the 135-kD subunit of TFIIIC and also to TBP. Surprisingly, in addition to binding the TFIIB-homologous amino-terminal portion of BRF, TBP also interacts strongly with the carboxy-terminal half. Deleting two conserved regions in the BRF carboxy-terminal region abrogates this interaction. Furthermore, TBP mutations that selectively inhibit Pol III transcription in vivo impair interactions between TBP and the BRF carboxy-terminal domain. Finally, we demonstrate that BRF but not TFIIB binds the Pol III subunit C34 and we define a region of C34 necessary for this interaction. These observations provide insights into the roles performed by BRF in Pol III transcription complex assembly.
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PMID:Conserved functional domains of the RNA polymerase III general transcription factor BRF. 799 25

Photoactive 4-thiodeoxythymidine 5'-triphosphate (4-S-dTTP) has been synthesized and used to enzymatically incorporate the corresponding nucleotide, 4-thiodeoxythymidine 5'-phosphate (4-S-dTMP), at specific positions of the Saccharomyces cerevisiae 5 S rRNA and SUP4 tRNA(Tyr) genes. RNA polymerase III transcription complexes have been assembled on this DNA and analyzed by photocrosslinking for proteins making close contact with DNA. Comparison DNA probes with a long-tether photoactive nucleotide 5-[N-(p-azidobenzoyl)-3-aminoallyl]-dUMP (N3RdUMP) incorporated at the same positions have also been analyzed, in order to compare the properties of these two crosslinking reagents. At least 10 of the 16 different S. cerevisiae polymerase III subunits make direct contact with DNA. The 120-kDa subunit of transcription factor (TF)IIIC, which is thought to play the key role in positioning TFIIIB upstream of the transcriptional start site, also contacts DNA near the transcriptional start site in TFIII(C+B) complexes with a SUP4 tRNA(Tyr) gene. The photocrosslinking patterns generated by 4-S-dTMP and N3RdUMP are distinctive, implying that these two reagents can yield complementary information about the structures of complex protein assemblies on DNA. Surprisingly, some subunits of the S. cerevisiae RNA polymerase III are crosslinked by 4-S-dTMP but not by N3RdUMP.
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PMID:Probing close DNA contacts of RNA polymerase III transcription complexes with the photoactive nucleoside 4-thiodeoxythymidine. 802 70

Yeast transcription factor TFIIIB is a multicomponent factor comprised of the TATA-binding protein TBP and of associated factors TFIIIB70 and B". Epitope-tagged or histidine-tagged TFIIIB70 could be quantitatively removed from TFIIIB by affinity chromatography. TBP and B" (apparent mass 160-200 kDa) could be easily separated by gel filtration or ion-exchange chromatography. While only weak interactions were detected between TBP and B", direct binding of [35S]-labeled TBP to membrane-bound TFIIIB70 could be demonstrated in absence of DNA. On tRNA genes, there was no basal level of transcription in the complete absence of TBP. The two characterized TFIIIB components (recombinant rTFIIIB70 and rTBP) and a fraction cochromatographing with B" activity were found to be required for TFIIIC-independent transcription of the TATA-containing U6 RNA gene in vitro. Therefore, beside the TFIIIC-dependent assembly process, each TFIIIB component must have an essential role in DNA binding or RNA polymerase recruitment.
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PMID:Interactions between yeast TFIIIB components. 751 81

We report the characterization of a mutation affecting tau 138, the largest subunit of yeast transcription factor IIIC (TFIIIC). A previously described thermosensitive mutation (tsv115), tightly linked to the centromere of chromosome I (Harris, S.D., and Pringle, J.R. (1991) Genetics 127, 279-285) is shown to lie in the TFC3 gene which encodes tau 138. The tau 138 subunit carrying this mutation bears a single substitution of Glu for Gly at position 349 (G349E). In extracts from mutant cells, both the level of TFIIIC and its affinity for tDNA were found to be reduced. The tDNA binding activity of mutant TFIIIC protein was very sensitive to mild heat treatments, and TFIIIC-DNA interaction was inhibited at moderate salt concentrations, as evidenced by gel shift assays. In addition, the tsv115 mutation affected 5 S RNA synthesis in vitro, suggesting that the tau 138 subunit also plays a role in recognition of the TFIIIA-5 S DNA complex. Multicopy suppressors of the TFIIIC defect were sought to reveal components participating in TFIIIC function. One class of suppressors encodes known components of the transcription machinery: two TFIIIC subunits, tau 95 and tau 131, the 70-kDa subunit of TFIIIB, TBP, and a shared subunit of RNA polymerase (pol) I, II, and III, ABC10 alpha; it also includes genes potentially related to pol III function, such as SRP40 which also suppresses a mutation in a subunit shared by RNA polymerases I and III. A second class of suppressors is not involved in transcription but alleviates the main physiological defects of mutant cells. It includes RPR1 and NOP1, required for the maturation of pre-tRNA and pre-rRNA, respectively.
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PMID:A mutation in the largest subunit of yeast TFIIIC affects tRNA and 5 S RNA synthesis. Identification of two classes of suppressors. 808 43

Constitutive and silk gland-specific tRNA(Ala) genes from silkworms have very different transcriptional properties in vitro. Typically, the constitutive type, which encodes tRNA(AlaC), directs transcription much more efficiently than does the silk gland-specific type, which encodes tRNA(AlaSG). We think that the inefficiency of the tRNA(AlaCG) gene underlies its capacity to be turned off in non-silk gland cells. An economical model is that the tRNA(AlaSG) promoter interacts poorly, relative to the tRNA(AlaC) promoter, with one or more components of the basal transcription machinery. As a consequence, the tRNA(AlaSG) gene directs the formation of fewer transcription complexes or of complexes with reduced cycling ability. Here we show that the difference in the number of active transcription complexes accounts for the difference in tRNA(AlaC) and tRNA(AlaSG) transcription rates. To determine whether a particular component of the silkworm transcription machinery is responsible for reduced complex formation on the tRNA(AlaSG) gene, we measured competition by templates for defined fractions of this machinery. We find that the tRNA(AlaSG) gene is greatly impaired, in comparison with the tRNA(AlaC) gene, in competition for either TFIIIB or RNA polymerase III. Competition for each of these fractions is also strongly influenced by the nature of the 5' flanking sequence, the promoter element responsible for the distinctive transcriptional properties of tRNA(AlaSG) and tRNA(AlaC) genes. These results suggest that differential interaction with TFIIIB or RNA polymerase III is a critical functional distinction between these genes.
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PMID:Silk gland-specific tRNA(Ala) genes interact more weakly than constitutive tRNA(Ala) genes with silkworm TFIIIB and polymerase III fractions. 811 13

Extracts from whole oocytes of Xenopus laevis are widely used as an efficient in vitro system for the transcription of cloned genes by RNA polymerase III. We have found that these extracts no longer support RNA polymerase III transcription in response to a brief incubation in the presence of Ca2+. However, when transcription complexes were first formed on the genes, a subsequent incubation in the presence of Ca2+ had little effect. Fractionation of extracts was used to show that transcription factors (TF) IIIC and, to a lesser extent, TFIIIB, but not RNA polymerase III, were targets of the Ca(2+)-dependent inactivation process. An additional component (not present in fractionated TFIIIC or TFIIIB) was required for the Ca(2+)-dependent destruction of transcription factor activity. The Ca(2+)-dependent inactivation process was blocked by protease inhibitors that inhibit known Ca(2+)-dependent proteases called calpains. These results suggest that TFIIIC and TFIIIB are inactivated by an endogenous calpain. The common use of Ca2+ as a second messenger and the widespread distribution of calpains suggest that the proteolytic degradation of transcription factors may be a general mechanism for the regulation of gene expression.
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PMID:Calcium-dependent inactivation of RNA polymerase III transcription. 811 9

tRNA(IleIAU) provides an activity, originally called TFIIIR, necessary to reconstitute transcription by silkworm RNA polymerase III in vitro from partially purified components. Here we report studies on the role of tRNA(IleIAU) in in vitro transcription. We show that tRNA(IleIAU) does not act positively but, rather, is required to prevent the action of a transcriptional inhibitor. We also show that the presence of tRNA(IleIAU) in transcription reaction mixtures prevents low-frequency DNA cleavage by the TFIIIB fraction. Studies on the mechanism of transcriptional inhibition suggest that this DNA cleavage could cause transcriptional inhibition through trans-inactivation of transcription machinery. The ability to block DNA cleavage, like the ability to facilitate transcription, is highly specific to silkworm tRNA(IleIAU).
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PMID:tRNA(IleIAU) (TFIIIR) plays an indirect role in silkworm class III transcription in vitro and inhibits low-frequency DNA cleavage. 819 5

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