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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)

We have studied the interactions of the Sp1 and IID transcription factors with a simple RNA polymerase II promoter. The adenovirus E1B core promoter consists essentially of a GC box and a TATA box, binding sites for the Sp1 and IID transcription factors, respectively. The E1B promoter is accurately transcribed in vitro using a mammalian transcription system. Sp1 activates E1B transcription in vitro in reactions using IID factor isolated from either human or yeast cells. In DNase I footprinting studies, Sp1 bound rapidly to its recognition sequence even at 0 degrees C (t1/2 less than 1 min). In contrast, yeast IID bound more slowly (t1/2 approximately 6 min at 25 degrees C) and required thermal energy for stable binding to the TATA box sequence. Dissociation rates were measured by the addition of specific oligonucleotide competitors to preformed DNA-protein complexes. Sp1 dissociates rapidly (t1/2 less than 1 min) at 25 degrees C, while yeast IID dissociates with an estimated t1/2 of 1 h at 25 degrees C. Sp1 and yeast IID bound to the E1B promoter simultaneously but independently. The rates of binding and dissociation of these factors were not significantly affected by the presence of the other factor. Bound Sp1 factor did not alter or enhance the yeast IID footprint. Oligonucleotide challenge of in vitro transcription reactions indicated that Sp1 also did not enhance the binding of the human IID factor to the E1B promoter. Thus the Sp1 factor activates transcription of the E1B gene by a mechanism that does not enhance the DNA-binding activity of the IID factor. Sp1 factor activates E1B transcription by 5- to 10-fold in vitro. Under these in vitro transcription conditions, transcripts due to reinitiation from an individual promoter complex contribute only a small portion of the total yield of E1B transcripts. Thus Sp1 cannot activate transcription by increasing the rate of initiation events per complex. Instead it appears that Sp1 acts by increasing the number of productive transcription complexes formed in vitro.
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PMID:Sp1 activates transcription without enhancing DNA-binding activity of the TATA box factor. 267 69

The yeast homolog of the mammalian RNA polymerase II general transcription factor TFIIA has been identified by complementation of a mammalian in vitro transcription system depleted for TFIIA. Like the mammalian factor, the yeast protein does not bind DNA, alters the size of the TFIID DNase I footprint at the adenovirus major late promoter, and forms specific TFIIA-TFIID-DNA complexes which are stable during electrophoresis in native acrylamide gels. The partially purified yeast factor was used to investigate its effect on the binding of TFIID to the major late promoter. Contrary to earlier models, we find that TFIIA does not significantly change the affinity or kinetics of TFIID binding, suggesting that it acts by altering the conformation of TFIID and/or by serving as a bridge between TFIID and the other general transcription factors.
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PMID:Identification of a yeast protein homologous in function to the mammalian general transcription factor, TFIIA. 268 41

A new experimental approach, site-directed chemical modification, was used to explore relationships between RNA polymerase-promoter interactions and function. For this study, the lacUV5 promoter with an exposed -10 thymine on the non-template strand was constructed. Osmium tetroxide was selected as the thymine modifying reagent. Modification occurred predominantly at the exposed -10 T with 5-fold less reactivity at the -12 T residue. The isolated modified strand was used to reconstitute a lacUV5 promoter with -10 (-12) adducts. OsO4 modification at both the -10 and -12 positions of the lacUV5 promoter significantly enhances Escherichia coli RNA polymerase-promoter open complex formation relative to the unmodified promoter. DNase I cleavage sites at -7, -8, and -10 of the unmodified promoter were rendered insusceptible to scission in the modified promoter. However, no difference can be detected in the RNA polymerase footprints for unmodified versus modified open complexes. The latter are fully capable of productive transcription with comparable amounts of identical run-off transcripts to unmodified open complexes. A 16 degrees C reduction in Tm was found for a 14-base pair oligonucleotide duplex containing a single OsO4-bispyridine adduct. The latter result suggests that open complex formation appears to be enhanced due to promoter unpairing at the -10 (-12) adduct sites.
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PMID:Site-directed chemical modification for probing DNA-protein interactions. Osmium tetroxide modification of the -10 site of the lacUV5 promoter enhances open complex formation. 268 77

Xenopus transcription factor IIIA (TFIIIA) or TFIIIA mutants with internal deletions were expressed in E. coli utilizing a bacteriophage T7 RNA polymerase system. TFIIIA or deletion mutant TFIIIAs, isolated from E.coli cell extracts, were identified by SDS PAGE and immunoblotting with rabbit antiserum against native TFIIIA purified from Xenopus immature oocytes. Specific DNA binding of intact or internally deleted TFIIIA was compared by analyzing their abilities to protect the internal control gene (ICR) of the Xenopus 5S RNA gene from DNase I digestion. Intact protein, synthesized from a full-length TFIIIA cDNA, bound specifically to the entire ICR (+96 to +43) and promoted 5S RNA gene transcription in vitro. One TFIIIA deletion mutant, expressed from cDNA lacking the coding sequence for the putative fourth zinc finger (designated from the N-terminus, amino acids 103-132) protected the ICR from DNase I digestion from nucleotide positions +96 to +78. A second TFIIIA mutant resulting from fusion of putative zinc fingers 7 and 8 (deletion of amino acids 200-224) protected the 5S gene ICR from positions +96 to +63. The DNase I protection patterns of these mutant proteins are consistent with the formation of strong ICR contacts by those regions of the protein on the N-terminal side of the mutation but not by those regions on the C-terminal side of the mutation. The regions of the protein comprising the N-terminal 3 fingers and N-terminal six fingers appear to be in contact with approximately 18 and 33 bp of DNA respectively on the 3' side of the 5S gene ICR. These internal deletion mutants promoted 5S RNA synthesis in vitro and DNA renaturation.
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PMID:Internal deletion mutants of Xenopus transcription factor IIIA. 269 11

An activity (designated BTF1Y) in extracts of Saccharomyces cerevisiae can substitute for the human TATA box-binding factor BTF1 in a reconstituted transcription system containing the adenovirus 2 major late promoter, RNA polymerase B (II), and the basic transcription factors BTF2, BTF3, and STF. We have purified BTF1Y to homogeneity, using as assays reconstitution of in vitro transcription and DNase I footprinting on the TATA element. Both activities copurified with a 27-kDa polypeptide as determined by SDS/PAGE. Gel filtration indicated a molecular mass of 28 +/- 5 kDa under nondenaturing conditions, suggesting that the native BTF1Y protein is a monomer. BTF1Y was enzymatically cleaved, several peptides were sequenced, and appropriate oligonucleotide probes were synthesized to clone the BTF1Y gene from a yeast genomic library. The BTF1Y gene contains a 720-base-pair open reading frame encoding a protein of 27,003 Da. The recombinant protein expressed in HeLa cells exhibited the same chromatographic characteristics and in vitro transcriptional activity as BTF1Y prepared from yeast extracts, confirming the identity of the gene. Gene-disruption experiments indicated that the yeast BTF1Y gene is a single-copy essential gene.
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PMID:Cloning of the gene encoding the yeast protein BTF1Y, which can substitute for the human TATA box-binding factor. 269 73

Using the gel retardation assay we have identified a protein that can specifically bind to a site within the enhancer of the 37S pre-ribosomal RNA operon in yeast, as well as to a site 210 bp upstream of the site of transcription initiation of this operon. This protein (RBP1) has been partially purified by means of heparin-agarose chromatography and protects 20 bp in the rDNA enhancer, and 25 bp in the initiation region, against DNase I in an in vitro footprinting assay. In vivo footprinting studies using methylation of intact yeast cells with dimethylsulphate, indicate that the same binding sites are occupied in vivo as well. Deletions that abolish binding of RBP1 to the enhancer in vitro, as well as linker insertions into the RBP1 binding site in the initiation region that strongly diminish in vitro binding of RBP1, have no effect whatsoever on the enhancement of rDNA transcription in vivo. This was studied by deletion/mutation of the RBP1 binding site in vitro in an artificial ribosomal minigene and measuring the effect on the minigene transcription in vivo in yeast cells, transformed with the deleted/mutated minigenes. It can therefore be concluded that binding of RBP1 is not an important parameter in the functioning of the rDNA enhancer in yeast. Using the same minigene system we also show that RBP1 is not involved in termination of RNA polymerase I (Pol I) transcription at the main terminator T2.
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PMID:A yeast ribosomal DNA-binding protein that binds to the rDNA enhancer and also close to the site of Pol I transcription initiation is not important for enhancer functioning. 269 53

By deletion-transfection analysis, a region of the rat growth hormone gene has been identified which directs accurate, thyroid hormone responsive transcriptional initiation in vivo. In addition, a thyroid hormone-responsive DNase I hypersensitive domain containing three discrete hypersensitive sites has been identified near the GH promoter. One site is coincident with the TATA homology, and the others lie approximately 150 nucleotides 5' and 3' of this sequence. The TATA and 5' flanking DNA hypersensitive sites are located in the region of the gene which promotes hormone-responsive gene transcription. Based on these results, it is possible that the molecular basis for thyroid hormone induction of GH gene transcription includes binding of the occupied receptor to chromatin sites flanking the TATA homology, promoting binding of the TATA activating protein to this sequence. Together, these events may enhance the rate of RNA polymerase II initiation at the promoter.
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PMID:Thyroid hormone transcriptional regulatory region of the growth hormone gene. 269 51

It has been previously shown that heparin can bind to chromatin and enhance transcriptional activity. To characterize this phenomenon further, we have studied the interaction of heparin with isolated core mononucleosomes from avian reticulocytes. The results of these studies suggest that heparin bound reversibly to intact core mononucleosomes to induce a new structure, identified by decreased electrophoretic mobility and altered circular dichroism spectra. This altered nucleosome conformation exhibits 3-5-fold increased sensitivity to digestion by the nuclease, DNase I, and allows more efficient passage of RNA polymerase. At higher concentrations of heparin, core histones were completely removed from DNA. The finding of a reversible nucleosome-heparin complex in which core DNA is readily accessible to both RNA polymerase and the nuclease DNase I is discussed in the context of transcriptionally active chromatin.
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PMID:Heparin binds to intact mononucleosomes and induces a novel unfolded structure. 274 51

Citrobacter freundii encodes an inducible chromosomal beta-lactamase. Induction requires the product of the ampR gene, which is transcribed in the opposite orientation from the ampC beta-lactamase gene. We show here that the AmpR protein acts as a transcriptional activator by binding to a DNA region immediately upstream of the ampC promoter. The DNase I footprint pattern was not affected by growth in the presence of beta-lactam inducer or by the use of extracts prepared from cells carrying the ampD2 allele leading to semiconstitutive production of beta-lactamase. It is suggested that activation of AmpR facilitates binding or open complex formation for RNA polymerase at the ampC promoter. The AmpR-binding site overlaps the ampR promoter, and beta-galactosidase activity was decreased from an ampR-lacZ transcriptional fusion when AmpR was expressed from a coresident plasmid, suggesting that ampR is autogenously controlled. The AmpR protein belongs to a family of highly homologous transcriptional activators that includes LysR, which regulates the E. coli lysine synthetase gene, and the NodD protein, which regulates expression of a number of genes involved in nodulation in Rhizobium. The lack of sequence homology to any known beta-lactam-binding protein suggests that AmpR does not bind directly to the beta-lactam inducer but interacts with a second messenger of unknown nature.
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PMID:Binding of the Citrobacter freundii AmpR regulator to a single DNA site provides both autoregulation and activation of the inducible ampC beta-lactamase gene. 278 68

The region of the bacteriophage S13 genome which contains the B, K, and C genes and most of the A, D, and E genes (map positions 627 to 2198) was analyzed for Escherichia coli RNA polymerase-binding sites by combined DNase I footprinting, exonuclease III analysis, and DNA sequencing. Two high-affinity binding sites that correspond to the B and D gene promoters were mapped at positions 936 to 995 and 1779 to 1848, respectively. Positions 936 to 995 are in gene A, preceding the B gene, and positions 1779 to 1848 are in gene C, just preceding the D gene. In addition, two lower-affinity binding sites were identified at positions 1527 to 1538 and 1705 to 1756 preceding the C and D genes, respectively. The footprinting studies described here, in combination with previous studies on transcription, provide definitive evidence on the position of the B and D gene promoters in S13 and the closely related phage phi X174.
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PMID:Mapping the B and D gene promoters of bacteriophage S13 by footprinting and exonuclease III analysis. 282 8


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