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)

Transcription factor IIIB (TFIIIB), which by itself does not bind stably or specifically to DNA, was purified from cytoplasmic extracts of HeLa cells using five different chromatographic steps. This procedure yields one predominant polypeptide which represents 90% of the most highly purified preparation and shows a relative molecular mass of 60,000, when analyzed on sodium dodecyl sulfate-polyacrylamide gels. A similar value was obtained for the native protein by rate zonal centrifugation on glycerol gradients. From these data we conclude that TFIIIB from HeLa cells has a Mr of 60,000 +/- 5,000 and that it functions as a single polypeptide. Highly purified TFIIIB was required and sufficient for the specific transcription of the Xenopus laevis and human tRNA and 5 S RNA genes as well as those for VA RNA when reconstituted with RNA polymerase III and the other appropriate transcription factors.
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PMID:Purification of transcription factor IIIB from HeLa cells. 341 60

Transcription factor IIH (TFIIH) contains a kinase capable of phosphorylating the carboxy-terminal domain (CTD) of the largest subunit of RNA polymerase II (RNAPII). Here we report the identification of the Cdk-activating kinase (Cak) complex (Cdk7 and cyclin H) as a component of TFIIH after extensive purification of TFIIH by chromatography. We find that affinity-purified antibodies directed against cyclin H inhibit TFIIH-dependent transcription and that both cyclin H and Cdk7 antibodies inhibit phosphorylation of the CTD of the largest subunit of the RNAPII in the preinitiation complex. Cak is present in at least two distinct complexes, TFIIH and a smaller complex that is unable to phosphorylate RNAPII in the preinitiation complex. Both Cak complexes, as well as recombinant Cak, phosphorylate a CTD peptide. Finally, TFIIH was shown to phosphorylate both Cdc2 and Cdk2, suggesting that there could be a link between transcription and the cell cycle machinery.
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PMID:Cdk-activating kinase complex is a component of human transcription factor TFIIH. 753 95

Transcription factor TFIIIB plays a central role in transcription initiation by RNA polymerase III on genes encoding tRNA, 5S rRNA, and other small structural RNAs. We report the purification of a human TFIIIB-derived complex containing only the TATA-binding polypeptide (TBP) and a 90-kDa subunit (TFIIIB90) and the isolation of a cDNA clone encoding the 90-kDa subunit. The N-terminal half of TFIIIB90 exhibits sequence similarity to the yeast TFIIIB70 (BRF) and the class II transcription factor TFIIB and interacts weakly with TBP. The C-terminal half of TFIIIB90 contains a high-mobility-group protein 2 (HMG2)-related domain and interacts strongly with TBP. Recombinant TFIIIB90 plus recombinant human TBP substitute for human TFIIIB in a complementation assay for transcription of 5S, tRNA, and VA1 RNA genes, and both the TFIIB-related domain and the HMG2-related domain are required for this activity. TFIIIB90 is also required for transcription of human 7SK and U6 RNA genes by RNA polymerase III, but apparently within a complex distinct from the TBP/TFIIIB90 complex.
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PMID:Structure and function of a human transcription factor TFIIIB subunit that is evolutionarily conserved and contains both TFIIB- and high-mobility-group protein 2-related domains. 762 63

Transcription factor TFIIB is essential for the formation of RNA polymerase II initiation complexes where it binds to the TATA-binding protein (TBP) complex with DNA and recruits RNA polymerase II. TFIIB is probably a target for various activators. Several models have been proposed for the position of TFIIB in the TFIIB-TBP-DNA complex. Here we examine the structure of this complex using gel mobility-shift assays and hydroxyl-radical footprinting. TFIIB requires at least seven base pairs of DNA on either side of the TATA box to form a stable TFIIB-TBP-DNA complex. The sugar residues protected from hydroxyl-radical cleavage by the TFIIB-TBP complex were mapped on the crystal-structure model of the TBP-DNA complex. This analysis suggests that TFIIB binds beneath the concave surface of TBP, contacting DNA both upstream and downstream of the TATA box. Our model predicts that TFIIB binds close to the C-terminal stirrup of TBP and provides one explanation for why TBP needs to bend DNA.
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PMID:Model for binding of transcription factor TFIIB to the TBP-DNA complex. 763 13

RNA polymerase II (Pol II) requires seven general transcription factors (GTFs) and ATP for transcription initiation. Transcription factor IIH (TFIIH) has emerged as the sole GTF with enzymatic activity. In addition to its essential role in transcription initiation, recent studies have demonstrated a direct involvement of TFIIH in DNA excision repair processes. The enzymatic properties and functional duality of TFIIH make it a prime target for regulation by viral and cellular factors.
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PMID:The multifunctional TFIIH complex and transcriptional control. 785 96

The functions of individual basal transcription factors during the formation of an initiation complex by RNA polymerase II remain largely unknown. Transcription factor IIE (TFIIE) has recently been shown to bind to multiple targets in the initiation complex. To assess the role of zinc binding in basal transcription, we have mutated the predicted zinc-finger domain of human TFIIE. Atomic absorption spectroscopy using purified recombinant proteins revealed that the large subunit, TFIIE-56, is indeed a zinc-binding protein. Mutation of a cysteine residue in the putative zinc-finger domain abolished zinc binding. Moreover, mutant TFIIE-56 failed to support reconstituted basal transcription in vitro, suggesting that zinc binding is required for TFIIE function. However, gel-filtration experiments and protein affinity experiments suggest that mutant TFIIE-56 forms a stable heterotetramer with the small subunit, TFIIE-34, that is similar to wild type. Interestingly, gel mobility shift experiments reveal that loss of transcriptional activity by mutant TFIIE is correlated with its inability to stably assemble into the transcription complex. These findings establish that zinc binding by TFIIE may help form a specific structure that is required for stable entry into the transcription complex.
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PMID:Transcriptional activity of transcription factor IIE is dependent on zinc binding. 793

Transcription factor IIIC (TFIIIC) is a multisubunit basic TF for RNA polymerase III. It initiates transcription complex assembly on tRNA and related genes by binding to the internal box B promoter element and is also required for transcription of 5S rRNA and other stable nuclear and cytoplasmic RNAs transcribed by polymerase III. In mammalian cells, regulation of TFIIIC activity controls overall polymerase III transcription in response to growth factors and viral infection. Here, we report the cloning and sequencing of a full-length cDNA (and genomic DNA from the transcription initiation region) encoding the box B binding subunit of human TFIIIC, the 243-kDa alpha subunit. Specific antisera raised against the encoded protein super shifts a TFIIIC-box B DNA complex during an electrophoretic mobility shift assay and immunodepletes TFIIIC transcriptional activity from a partially purified TFIIIC fraction, proving that the cDNA encodes a component of TFIIIC. The human protein shows surprisingly little similarity to the box B binding subunit of yeast TFIIIC.
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PMID:Human transcription factor IIIC box B binding subunit. 812 61

Transcription factor IIIC (TFIIIC) binds in a sequence-specific manner to RNA-polymerase-III-transcribed genes (e.g. tRNA genes). It sequesters other transcription factors into the preformed complex, thereby activating transcription by RNA polymerase III. The Dictyostelium discoideum homologue of TFIIIC was highly purified by affinity chromatography based on its tDNA-binding activity. This TFIIIC homologue is a multicomponent factor (molecular mass 380 kDa), which binds to the B-box element of the internal tRNA gene promoter without significant A-box interaction. Partially purified D. discoideum TFIIIC is able to functionally complement a human RNA polymerase III in vitro transcription system depleted of human TFIIIC. We provide evidence that partially purified D. discoideum TFIIIC interacts in vitro with gene-external B-box elements present down-stream of many D. discoideum tRNA genes.
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PMID:Isolation of transcription factor IIIC from Dictyostelium discoideum. 814 38

Transcription factor IIIC (TFIIIC) is required for the assembly of a preinitiation complex on 5S RNA, tRNA, and adenovirus VA RNA genes and contains two separable components, TFIIIC1 and TFIIIC2. TFIIIC2 binds to the 3' end of the internal control region of the VAI RNA gene and contains five polypeptides ranging in size from 63 to 220 kDa; the largest of these directly contacts DNA. Here we describe the cloning of cDNAs encoding all (rat) or part (human) of the 220-kDa subunit (TFIIIC alpha). Surprisingly, TFIIIC alpha has no homology to any of the yeast TFIIIC subunits already cloned, suggesting a significant degree of evolutionary divergence for RNA polymerase III factors. Antibodies raised against the N terminus of recombinant human TFIIIC alpha specifically inhibit binding of natural TFIIIC to DNA. Furthermore, immunodepletion assays indicate that TFIIIC alpha is absolutely required for RNA polymerase III transcription of 5S RNA, tRNA, and VAI RNA genes but not for the 7SK RNA and U6 small nuclear RNA genes. Transcription from the tRNA and VAI RNA genes in TFIIIC-depleted nuclear extracts can be restored by addition of purified TFIIIC. In contrast, restoration of 5S RNA gene transcription requires readdition of both TFIIIC and TFIIIA, indicating a promoter-independent interaction between these factors. Immunoprecipitation experiments demonstrate a tight association of all five polypeptides previously identified in the TFIIIC2 fraction, confirming the multisubunit structure of the human factor.
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PMID:Cloning and characterization of an evolutionarily divergent DNA-binding subunit of mammalian TFIIIC. 816 61

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

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