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 TATA box-binding protein TBP directs transcription by all three eukaryotic RNA polymerases. In mammalian cells, TBP is found in at least three different complexes: SL1, D-TFIID, and B-TFIID. While SL1 and D-TFIID are involved in RNA polymerase I and II transcription, respectively, no unique function has been assigned to the B-TFIID complex. Here we show that the TFIIIB fraction required for RNA polymerase III transcription contains two separable components, one of which is a TBP-containing complex that may correspond to B-TFIID. For transcription of TATA-less RNA polymerase III genes such as the VAI, 5S, and 7SL genes, this complex cannot be replaced by either TBP alone or the D-TFIID complex. In contrast, TBP alone is active for basal transcription from the TATA-containing U6 promoter. This indicates different requirements for recruiting TBP to TATA-less and TATA-containing RNA polymerase III promoters.
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PMID:A TBP complex essential for transcription from TATA-less but not TATA-containing RNA polymerase III promoters is part of the TFIIIB fraction. 145 34

We have investigated the requirement for TBP (TATA-binding protein) in transcription mediated by RNA polymerase III (pol III) in fractionated HeLa cell extracts. Two activities, TFIIIB and TFIIIC, found in phosphocellulose fractions PC B and PC C respectively, have been defined as necessary and sufficient, with pol III, for in vitro transcription of tRNA genes. Depletion of TBP from PC B, using antibodies raised against human TBP, is shown to inhibit the pol III transcriptional activity of the fraction. Furthermore, TBP is present in fractions with human TFIIIB activity, and a proportion of TBP cofractionates with TFIIIB over four chromatographic purification steps. TFIIIB fractions are capable of supplying TBP in the form necessary for pol III transcription, and cannot be substituted by fractions containing other TBP complexes or TBP alone. The use of a 5S RNA gene and two tRNA templates supports the general relevance of our findings for pol III gene transcription. Purified TFIIIB activity can also support pol II-mediated transcription, and is found in a complex of approximately 230kD, suggesting that TFIIIB may be the same as the previously characterized B-TFIID complex (1,2). We suggest that transcription by the three RNA polymerases is mediated by distinct TBP-TAF complexes: SL1 and D-TFIID for pol I and pol II respectively, and TFIIIB for pol III.
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PMID:Cofractionation of the TATA-binding protein with the RNA polymerase III transcription factor TFIIIB. 146 21

We have previously shown that the TATA-binding protein (TBP) and multiple TBP-associated factors (TAFs) are required for regulated transcriptional initiation by RNA polymerase II. Here we report the biochemical properties of the RNA polymerase I promoter selectivity factor, SL1, and its relationship to TBP. Column chromatography and glycerol gradient sedimentation indicate that a subpopulation of TBP copurifies with SL1 activity. Antibodies directed against TBP efficiently deplete SL1 transcriptional activity, which can be restored with the SL1 fraction but not purified TBP. Thus, TBP is necessary but not sufficient to complement SL1 activity. Analysis of purified SL1 reveals a complex containing TBP and three distinct TAFs. Purified TAFs reconstituted with recombinant TBP complement SL1 activity, and this demonstrates that TBP plus novel associated factors are integral components of SL1. These findings suggest that TBP may be a universal transcription factor and that the TBP-TAF arrangement provides a unifying mechanism for promoter recognition in animal cells.
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PMID:The TATA-binding protein and associated factors are integral components of the RNA polymerase I transcription factor, SL1. 154 96

Faithful and efficient transcription initiation at the mouse ribosomal gene promoter requires besides RNA polymerase I (pol I) four polypeptide trans-acting factors, termed TIF-IA, TIF-IB, TIF-IC, and mUBF. We have partially purified these proteins from cultured Ehrlich ascites cells and show that in the presence of TIF-IA and TIF-IB, pol I directs very low amounts of specific transcripts. Neither TIF-IC nor mUBF on their own significantly stimulate the efficiency of template utilization. However, both factors together strongly activate transcription. Interestingly, factor TIF-IB - the murine homologue of human SL1 - fails to program a human extract to transcribe the murine template, but requires its homologous RNA polymerase I. This finding implicates that not only some rDNA transcription factors but also pol I exhibits species-specific differences. The growth-related factor TIF-IA, on the other hand, stimulates both mouse and human rDNA transcription. This regulatory factor whose amount or activity fluctuates according to the proliferation rate of the cells, is functionally inactivated by antibodies against cdc2 protein kinase. This result together with the observation that transcription is stimulated by ATP-gamma S, an ATP analogue which is a substrate for protein kinases but not for protein phosphatases, strongly suggests that post-translational protein modification is involved in rDNA transcription regulation.
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PMID:Trans-acting factors involved in species-specificity and control of mouse ribosomal gene transcription. 192 92

A doubly mutant ama-1(m118m526) gene results in an RNA polymerase (Rpo) II that is unusually resistant to alpha-amanitin. Rpo II activity in isolated Caenorhabditis elegans cell nuclei is inhibited 50% by alpha-amanitin at a concentration of 150 micrograms/ml, making this enzyme 150 times more resistant to the toxin than Rpo II from the singly mutant allele, ama-1(m118), 20,000 times more resistant than the wild-type Rpo II, and about six times more resistant to amanitin than is Rpo III. It was determined that the SL1 spliced leader precursor is transcribed by Rpo II, and this transcript was used to measure Rpo II activity. The Rpo II activity is unstable in vitro, and the mutant strain has a temperature-sensitive sterile phenotype. The highly resistant double mutant was selected among four million progeny of the mutagenized ama-1(m118) parent by its ability to grow and reproduce in 200 micrograms/ml amanitin in the presence of a permeabilizing agent, Triton X-100.
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PMID:Mutant Caenorhabditis elegans RNA polymerase II with a 20,000-fold reduced sensitivity to alpha-amanitin. 207 19

The eukaryotic upstream binding factor (UBF), recognizes the ribosomal RNA gene promoter and activates transcription mediated by RNA polymerase I through cooperative interactions with the species-specific factor, SL1. Isolation of complementary DNA clones and sequence analysis reveals similarities between DNA binding domains of human UBF (hUBF) and high mobility group (HMG) protein 1. Expression, cellular localization and in vitro transcription studies establish that cloned hUBF encodes a nucleolar factor that binds specifically to the upstream control element and core of the rRNA gene promoter to activate transcription in a binding site-dependent manner.
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PMID:Nucleolar transcription factor hUBF contains a DNA-binding motif with homology to HMG proteins. 233 41

How can trans-activators with the same DNA binding specificity direct different transcriptional programs? The rRNA transcriptional apparatus offers a useful model system to address this question and to dissect the mechanisms that generate alternative transcription complexes. Here, we compare the mouse and human transcription factors that govern species-specific RNA polymerase I promoter recognition. We find that both human and mouse rRNA transcription is mediated by a specific multiprotein complex. One component of this complex is the DNA-binding transcription factor, UBF. Paradoxically, human and mouse UBF display identical DNA binding specificities even though transcription of rRNA is species specific. Promoter selectivity is conferred by a second essential factor, SL1, which, for humans, does not bind DNA independently but, instead, cooperates with UBF in the formation of high-affinity DNA-binding complexes. In contrast, mouse SL1 can selectively interact with DNA in the absence of UBF. Reconstituted transcription experiments establish that UBF and RNA polymerase I from the two species are functionally interchangeable, whereas mouse and human SL1 exhibit distinct DNA binding and transcription activities. Together, these results suggest a critical role for a specific multiprotein assembly in RNA polymerase I promoter recognition and reveal distinct mechanisms through which such complexes can generate functional diversity.
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PMID:Assembly of alternative multiprotein complexes directs rRNA promoter selectivity. 238 15

The human ribosomal RNA promoter contains two distinct control elements (UCE and core) both of which are recognized by the sequence-specific DNA binding protein UBF1, which has now been purified to apparent homogeneity. The purified factor activates RNA polymerase I (RNA pol I) transcription through direct interactions with either control element. A second RNA pol I transcription factor, designated SL1, participates in the promoter recognition process and is required to reconstitute transcription in vitro. Although SL1 alone has no sequence-specific DNA binding activity, deoxyribonuclease I footprinting experiments reveal that a cooperative interaction between UBF1 and SL1 leads to the formation of a new protein-DNA complex at the UCE and core elements. In vitro transcription experiments indicate that formation of the UBF1-SL1 complex is vital for transcriptional activation by UBF1. Thus, protein-protein interactions between UBF1 and SL1 are required for targeting of SL1 to cis-control sequences of the promoter.
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PMID:Functional cooperativity between transcription factors UBF1 and SL1 mediates human ribosomal RNA synthesis. 341 83

The human rRNA promoter contains two distinct cis-control sequences, the core and upstream control element (UCE), that serve as the target for binding cellular trans-activating proteins involved in transcription initiation by RNA polymerase I. One of these factors, SL1, has been extensively purified and shown to be a species-specific factor required to reconstitute in vitro RNA synthesis. DNAase footprinting revealed that although SL1 alone does not bind specifically to rRNA promoter sequences, a second factor, UBF1, recruits SL1 to the template and directs binding to an extended region encompassing sequences in the UCE. Analysis of mutant and human-mouse hybrid promoters indicate that protein-DNA interactions at the UCE modulate the efficiency of rRNA synthesis. Transcription from the human rRNA promoter appears to require an unusual set of protein-DNA transactions in which recognition and binding to an upstream cis-control element is carried out by one factor (UBF1), whereas activation requires an additional factor, SL1, acting in conjunction with UBF1 to trigger transcription.
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PMID:Human rRNA transcription is modulated by the coordinate binding of two factors to an upstream control element. 370 92

A whole-cell HeLa extract was fractionated into two components required for accurate in vitro transcription of human rRNA. One fraction contained endogenous RNA polymerase I, and the second component contained a factor (SL1) that confers promoter selectivity to RNA polymerase I. Analysis of mutant templates suggests that the core control element of the rRNA promoter is required for activation of transcription by SL1. We purified SL1 approximately 100,000-fold by column chromatography and have shown that the addition of SL1 can reprogram the otherwise nonpermissive mouse transcription system to recognize and initiate accurate RNA synthesis from human rDNA. Antibodies raised against SL1 bind preferentially to a protein localized in the nucleolus of primate cells and specifically inhibit in vitro transcription initiating from the human rRNA promoter. By contrast, anti-SL1 does not react with the nucleolus of rodent cells and has no effect on the in vitro synthesis of mouse rRNA by a transcription system derived from mouse cells. These findings suggest that SL1 is a selectivity factor present in the nucleolus that imparts promoter recognition to RNA polymerase I and that can discriminate between rRNA promoters from different species.
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PMID:Purification and characterization of a transcription factor that confers promoter specificity to human RNA polymerase I. 392 71

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