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 general transcription factor TFIIE, together with other general transcription factors, is essential for transcription initiation by RNA polymerase II. TFIIE stimulates the TFIIH-dependent kinase activity that phosphorylates the carboxy-terminal domain of the largest subunit of RNA polymerase II, and possesses a helicase activity. Here we show that human TFIIH has DNA-dependent ATPase activity and we characterize the stimulatory effect of TFIIE on both the ATPase and kinase activities. We demonstrate that extensive phosphorylation of RNA polymerase II occurs in a TFIIE-dependent manner in both the absence and presence of DNA but, in the latter case, only at a late stage of preinitiation complex assembly. We also show that TFIIH specifically phosphorylates three general transcription factors, human TFIID tau (TBP), TFIIE-alpha and TFIIF-alpha (RAP74).
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PMID:Regulation of TFIIH ATPase and kinase activities by TFIIE during active initiation complex formation. 816 91

Transcription initiation by RNA polymerase II is effected by an ordered series of general factor interactions with core promoter elements (leading to basal activity) and further regulated by gene-specific factors acting from distal elements. Both the general factor TFIID (refs 2,3), including the constituent TBP (TATA-binding polypeptide) and associated factors, and the interacting factor TFIIB (refs 9-11) have been implicated as targets for various activators. Towards an understanding of the basis for activator function, including the multiplicity of TBP interactions, we have now identified mutations in yeast TBP that selectively block activator (GAL4-VP16)-dependent but not basal transcription. We further show an effect of GAL4-VP16 on TFIIB recruitment to early preinitiation complexes, and that recruitment is disrupted by TBP mutations that impair its interactions with VP16 (L114K), TFIIB (L189K) or an unidentified component (K211L). Thus, GAL4-VP16 function seems to involve both direct interactions with TBP and a corresponding induction (or stabilization) of an activation-specific TBP-TFIIB-promoter complex.
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PMID:Effects of activation-defective TBP mutations on transcription initiation in yeast. 818 47

TFIIA is a transcription factor that, by interacting with the TATA-binding subunit (TBP) of TFIID, modulates transcription initiation by RNA polymerase II in vitro. By use of a mobility shift assay, TFIIA was purified from HeLa cells as a complex of 35-, 19-, and 12-kD subunits. Oligonucleotides were used to isolate a human cDNA clone, hTFIIA/alpha, which encodes a 55-kD protein with homology to the product of the yeast gene TOA1. The open reading frame of hTFIIA/alpha contains peptide sequences obtained from both the p35 and p19 subunits of natural human TFIIA, and thus encodes these two subunits. Consistent with this, antiserum raised against the 55-kD hTFIIA/alpha-encoded protein reacted with both the p35 and p19 subunits of natural TFIIA, and the recombinant protein could functionally replace those subunits in a mobility shift assay with renatured p12. An efficient affinity purification for natural human TFIIA was suggested by the sequence of the hTFIIA/alpha protein and demonstrated biochemically. Finally, transcription from the adenovirus major late promoter was greatly reduced in nuclear extracts depleted with anti-TFIIA/alpha serum and was restored to original levels by the readdition of purified human TFIIA.
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PMID:A single cDNA, hTFIIA/alpha, encodes both the p35 and p19 subunits of human TFIIA. 822 48

In eukaryotes, initiation of mRNA synthesis is a multistep process that is carried out by RNA polymerase II and auxiliary factors that are commonly referred to as basal or general factors. In this study accurate initiation of transcription was reconstituted with purified, Escherichia coli-synthesized TFIIB, TBP (the TATA box-binding polypeptide of the TFIID complex), and the 30-kD subunit of TFIIF (also known as RAP30), along with purified, native RNA polymerase II from Drosophila embryos, calf thymus, or HeLa cells. This minimal set of factors was able to transcribe a subset of the promoters tested. The addition of both subunits of TFIIE and the 74-kD subunit of TFIIF increased the efficiency of transcription by a factor of 2 to 4. In contrast, the inclusion of a crude TFIID fraction from Drosophila embryos in place of recombinant TBP resulted in a strong dependence on TFIIE. By gel mobility-shift analysis, TFIIB, TBP, RAP30, and polymerase were able to assemble into DB and DBPolF30 complexes with transcriptionally competent (wild type or initiator mutant), but not with transcriptionally inactive (TATA and TATA/initiator mutant), versions of the Drosophila Adh promoter. Thus, it appears that RNA polymerase II is able to initiate transcription subsequent to assembly of the DBPolF30 complex, which is a minitranscription complex that represents the central core of the RNA polymerase II transcriptional machinery.
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PMID:Identification of a minimal set of proteins that is sufficient for accurate initiation of transcription by RNA polymerase II. 831 11

The ribosomal protein L32 (rpL32) gene transcribed by RNA polymerase II lacks a canonical TATA element, that binds the transcription factor TFIID tau or TBP (TATA binding protein). Instead this promoter contains an element, termed gamma, located at -30 relative to the transcription initiation site. We previously reported that, despite the lack of a canonical TATA element the rpL32 gene utilizes yeast TFIID tau for its transcriptional initiation. Whether TFIID tau participates in rpL32 gene transcription by binding directly to a promoter element or through another protein has not been resolved. These studies reveal that proteins ranging in size from 20-40 kDa binds to the gamma-element. The 40 kDa protein(s) displays strong affinity for the canonical TATA element and may be related or equivalent to TFIID tau. Furthermore, cloned and purified yeast TFIID (TBP) binds directly to the gamma-element implying that the gamma-element directs RNA polymerase II-dependent transcription of the rpL32 gene.
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PMID:Direct binding of yeast transcription factor (TFIID) to the ribosomal protein L32 (rpL32) TATA-less promoter sequence. 832 65

Transcription initiation from eukaryotic protein-coding genes is a complex process that minimally requires RNA polymerase (pol) II (B) and at least seven general transcription factors. The 38-kDa subunit (TBP) of the human general transcription factor TFIID recognizes the TATA sequence element and initiates the assembly of the other general transcription factors and RNA pol II. It is believed, based on experiments with yeast recombinant protein, that TBP binds as a monomer to DNA. Using purified recombinant human TBP protein we find that TBP interacts with the TATA element as both a monomer and a dimer. The multimeric binding of TBP to DNA revealed by this study has important implications for the role of TBP in transcription initiation and suggests novel mechanisms whereby other transcription factors may interact with a RNA pol II preinitiation complex.
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PMID:The DNA-binding subunit of human transcription factor IID can interact with the TATA box as a multimer. 834 93

The minimal promoter elements required for initiation by RNA polymerase II include the TATA box and/or an initiator element (Inr) at or near the transcription start site. Studies of the adenovirus major late core promoter (containing both elements) have demonstrated an initiation pathway that involves binding of the transcription factor TFIID (or the derived subunit, the TATA-binding protein TBP (TFIID tau)) to the TATA element, which is facilitated by transcription factor TFIIA, followed by sequential interactions of other general factors. Here we describe a novel pathway that requires an intact Inr and the Inr-binding factor TFII-I (ref. 3). Sequential addition of the general factors generated TFII-I-dependent preinitiation complexes different from those formed with TFIIA. Furthermore, TBP bound cooperatively (with only TFII-I) to an Inr-containing TATA-less promoter, suggesting a means for activation of TATA-less promoters, which nonetheless require TFIID (refs 9-11). These observations provide support for functionally distinct pathways which could be subject to differential regulation by specific activators or repressors.
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PMID:An alternative pathway for transcription initiation involving TFII-I. 837 28

The eukaryotic TATA-binding protein TBP, which is required for transcription by RNA polymerase II, is tightly associated with a particular set of factors in the TFIID complex, and as such provides a target for transcriptional regulation exerted by upstream factors. An embryonic carcinoma (EC) cell-specific activity like that of the viral factor E1A has been implicated in the mediation of transactivation from the retinoic acid receptor to human TBP, but yeast TBP cannot perform this function. Using TBP mutants with an altered TATA-box-binding specificity, we show here that yeast TBP can mediate transcriptional activation in mammalian cells and that its inability to convey retinoic acid-dependent transactivation in EC cells is due to specific residues in its core region. These residues preclude a functional association with the cellular E1A-like activity. TBP is thus a target for retinoic acid-dependent transactivation in EC cells by providing a surface for interaction with the EC cell-specific E1A-like activity.
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PMID:Residues in the TATA-binding protein required to mediate a transcriptional response to retinoic acid in EC cells. 841 15

The human p53 tumor suppressor gene product can activate transcription by RNA polymerase II in the yeast, Saccharomyces cerevisiae, as well as in human cells. Several viral transcriptional activator proteins have been shown to directly contact TBP, the TATA box-binding subunit of the general initiation factor, TFIID. In this report, we use protein affinity chromatography to show that the cellular transcription factor, p53, interacts directly and specifically with yeast TBP. The TBP binding domain of p53 was localized to its N-terminal 73 amino acids. This highly acidic portion of p53 functions as a transcriptional activation domain and is deleted in some tumors induced by the Friend leukemia virus. A human tumor-derived oncogenic point mutation of p53, which lies outside the activation domain of p53, but reduces its ability to activate transcription, greatly reduced the ability of p53 to bind yeast TBP in vitro. This mutation probably affects the overall conformation of the protein and indirectly interferes with the ability of p53 to contact TBP and activate transcription. In contrast, a mutated oncogenic form of p53 that is unaffected in its ability to activate transcription bound yeast TBP as well as wild type p53. The human TBP activity in a HeLa extract also bound to the activation domain of p53. Our data support a general model in which DNA-bound activator proteins activate transcription by interacting with TBP.
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PMID:Direct interaction between the transcriptional activation domain of human p53 and the TATA box-binding protein. 842 1

The TATA-binding protein TBP is necessary for the transcription of eukaryotic genes. Multi-protein complexes formed by TBP and different TBP-associated factors are involved in the initiation of transcription by polymerases I and II, and probably III as well. During the formation of an active initiation complex, TBP makes specific contacts with other proteins, for example TFIIB and RNA polymerase II (refs 2-4). Here we describe the cloning and characterization of a Drosophila gene product with considerable sequence similarity to TBP and a highly restricted expression pattern in the embryo. This TBP-related factor is a DNA-binding protein but is not likely to be a basal transcription factor. Our results suggest that TBP-related factor is a sequence-specific transcription factor that shares the DNA-binding properties of TBP.
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PMID:A new factor related to TATA-binding protein has highly restricted expression patterns in Drosophila. 842 12

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