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)

Phage fd DNA complexed with DNA binding protein I was used by Escherichia coli RNA polymerase (nucleoside triphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) to synthesize an RNA at the origin of single strand to double strand replication. The isolated ori-RNA gave a simple fingerprint after nucleolytic digestion and has a length of about 30 nucleotides. The characterization of the oligonucleotides from the nuclease digest and the extension of the ori-RNA with DNA polymerase I and subsequent restriction of the DNA gave its exact localization in the fd genome, and its total sequence was deduced from the known DNA sequence in this region.
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PMID:An RNA transcribed from DNA at the origin of phage fd single strand to replicative form conversion. 20 27

A critical regulatory element in many promoters transcribed by RNA polymerase II is the "TATA" box, which is located 25-30 nucleotides upstream of the transcription initiation site. TFIID is a biochemically defined HeLa cell nuclear fraction containing a transcription factor activity that binds specifically to the TATA box and is critical in determining both basal and regulated promoter activity. Recently, the gene for a TATA-binding protein was cloned and found to bind to various TATA elements and to substitute for TFIID in stimulating basal gene expression in in vitro transcription systems. However, it is possible that additional cellular factors can bind to the TATA element and influence the level of gene expression. By using lambda gt11 expression cloning with oligonucleotides corresponding to the human immunodeficiency virus 1 TATA element, we report the identification of a cellular protein with a calculated molecular mass of 123 kDa that we designate TATA element modulatory factor (TMF). TMF binds to the human immunodeficiency virus 1 TATA element in gel-retardation assays and inhibits activation of the viral long terminal repeat by the TATA-binding protein in in vitro transcription assays. TMF contains leucine-zipper amino acid motifs and exhibits homology in its DNA binding domain with the phage-encoded DNA binding protein Ner. Chromosomal mapping localizes the TMF gene to human chromosome 3p12-p21, which is a site of frequent rearrangements in lung and renal carcinomas. Thus, TMF is a transcription factor that likely regulates the expression of both viral and cellular genes.
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PMID:Cloning and chromosomal mapping of a human immunodeficiency virus 1 "TATA" element modulatory factor. 140 43

By using a DNase I footprinting assay, we have purified a factor by DNA affinity chromatography that binds to the minimal enhancer region of the Drosophila knirps gene and subsequently identified the protein as the core histone H2B. This inadvertent purification of a core histone as a putative sequence-specific DNA binding protein was due to a previously unknown property of H2B to interact with DNA in a periodic manner. Moreover, we found that each of the individual core histones, but not histone H1 or high mobility group protein 1, bound to the knirps enhancer to give a repetitive DNase I footprint pattern with a periodicity of about 10 base pairs, which is approximately one turn of the DNA helix. In addition, preparations containing the core histones H2A-H2B or H3-H4 yielded identical periodic DNase I footprint patterns on several different promoter and enhancer regions. These findings suggest that there are periodic, homotypic interactions between DNA-bound core histones that result from an alteration of the overall DNA structure such as the curvature rather than a specific sequence. We have also shown that histones H2A-H2B can repress initiation of transcription by RNA polymerase II. The phenomena described here may reflect histone-DNA interactions in non-nucleosomal stretches of chromatin and could be involved in some aspects of either rotational or translational positioning of nucleosomes. Furthermore, these findings indicate that a repeated 10 bp DNase I ladder, which has previously been considered to be a property of an intact nucleosome, can also be generated with subnucleosomal components. It will thus be necessary to reevaluate the criteria applied to the analysis of nucleosomes both in vivo and in vitro.
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PMID:Periodic binding of individual core histones to DNA: inadvertent purification of the core histone H2B as a putative enhancer-binding factor. 148 Apr 89

Transcription of the phage Mu com/mom operon is trans-activated by another phage gene product, C, a site-specific DNA binding protein. To gain insight into the mechanism by which C activates transcription, we carried out footprinting analyses of Escherichia coli RNA polymerase (= RNAP) binding to various com-lacZ fusion plasmids. KMnO4-sensitive sites (diagnostic of the melted regions in open-complexes) and DNase I-sensitive sites were located by primer-extension analysis. The results are summarized as follows: (i) in vivo, in the absence of C, RNAP bound in the wild-type (wt) promoter region at a site designated P2; in vitro DNase I-footprinting showed that P2 extends from -74 to -24 with respect to transcription initiation. This overlaps a known strong C-binding site (at -35 to -54). RNAP bound at P2 appeared to be in an open-complex, as evidenced by the presence of KMnO4-hypersensitive sites. (ii) In contrast, when C was present in vivo, RNAP bound in the wt promoter region at a different site, designated P1, located downstream and partially overlapping P2. RNAP bound at P1 also appeared to be in an open-complex, as evidenced by the presence of KMnO4-hypersensitive sites. (iii) Two C-independent mutants, which initiate transcription at the same position as the wt, were also analyzed. In vivo, in the absence of C, RNAP bound mutant tin7 (contains a T to G substitution at -14) predominantly at P1; in vitro DNase I-footprinting showed that P1 extends from -56 to +21. With mutant tin6 (a 63 base-pair deletion removing P2, as well as part of P1 and the C-binding site from -35 to -54), RNAP bound to P1 independent of C. We conclude that P1 is the 'functional' RNAP binding site for mom-transcription initiation, and that C activates transcription by promoting binding at P1, while blocking binding at P2.
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PMID:Functionally distinct RNA polymerase binding sites in the phage Mu mom promoter region. 153 36

We have investigated whether the RNA polymerase III-driven transcription of eukaryotic tRNA genes can be regulated by the prokaryotic tetracycline operator-repressor system. The bacterial tet operator (tetO) was inserted at two different positions (-7 and -46) upstream of a tRNA(Glu) (amber) suppressor gene. Both constructs are transcribed in Saccharomyces cerevisiae and yield functional tRNAs as scored by suppression of an amber nonsense mutation in the met8-1 allele. Controlled expression of Tet repressor was achieved by fusing the bacterial tetR gene to the yeast gal1 promoter. This leads to expression of Tet repressor in yeast on galactose--but not on glucose--containing media. Regulation of the su-tRNA gene with the tetO fragment inserted at position -7 has been demonstrated. Under conditions which allow tetR expression, cells exhibit a met- phenotype. This methionine auxotrophy can be conditionally reverted to prototrophy by adding tetracycline. However, a su-tRNA gene with the tetO fragment inserted at position -46 cannot be repressed. Our results demonstrate clearly that the bacterial repressor protein binds to its operator in the yeast genome. Formation of this complex in the vicinity of the pol III transcription initiation site reduces the level of su-tRNA at least 50-fold as concluded from quantitative primer extension analyses. This indicates for the first time that class III gene expression can be regulated by a DNA binding protein with its target site in the 5'-flanking region and that a prokaryotic repressor can confer regulation of a suitably engineered tRNA gene.
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PMID:RNA polymerase III catalysed transcription can be regulated in Saccharomyces cerevisiae by the bacterial tetracycline repressor-operator system. 156 52

Immediately upstream of the hmfB gene, in a DNA fragment cloned from Methanothermus fervidus, are two identical tandemly repeated copies of a 73-bp sequence that contain the sequence 5'TTTATATA, which conforms precisely to the consensus TATA box element proposed for methanogen promoters. By using this duplicated region as the template DNA and a cell-free transcription system derived from Methanococcus thermolithotrophicus, transcription in vitro was found to initiate at two identical sites 73 bp apart, each 25 bp downstream from a TATA box, thus providing strong evidence for the functional conservation of this transcriptional signal in two phylogenetically very diverse methanogens. Transcription of the hmfB gene in vivo in M. fervidus was found to occur at only one of these sites, and consistent with this observation, recloning and sequencing of this intergenic region after its amplification by the polymerase chain reaction demonstrated that the genome of M. fervidus contains only one copy of the 73-bp sequence upstream of the hmfB gene. Since the second copy of the 73-bp sequence, presumably generated artifactually during the original hmfB cloning, functioned equally well as a promoter in the M. thermolithotrophicus transcription system, all information needed by the heterologous RNA polymerase to initiate transcription accurately in vitro must be present within this sequence. The hmfB gene encodes HMf-2, one of the two subunits of HMf, an abundant DNA binding protein in M. fervidus which binds to DNA molecules in vitro, forming nucleosomelike structures. Cell-free transcription was inhibited by adding HMf or eucaryotic core histones at protein-to-DNA mass ratios of 0.3:1 and 1:1, respectively, whereas the archael histonelike protein HTa from Thermoplasma acidophilum inhibited transcription in vitro only at much higher protein-to-DNA mass ratios and the bacterial histonelike protein HU from Escherichia coli had no detectable effect on transcription.
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PMID:Transcription in vivo and in vitro of the histone-encoding gene hmfB from the hyperthermophilic archaeon Methanothermus fervidus. 159 6

UBF is a DNA binding protein which interacts with both the promoter and the enhancer of various vertebrate ribosomal RNA genes and functions as a transcription initiation factor for RNA polymerase I (pol I). We have purified murine UBF to apparent molecular homogeneity and demonstrate that its transactivating potential, but not its DNA binding activity, is modulated in response to cell growth. In vivo labelling experiments demonstrate that UBF is a phosphoprotein and that the phosphorylation state is different in growing and quiescent cells. We show that UBF is phosphorylated in vitro by a cellular protein kinase which by several criteria closely resembles casein kinase II (CKII). A major modification involves serine phosphoesterifications in the carboxy terminal hyperacidic tail of UBF. Deletions of this C-terminal domain severely decreases the UBF directed activation of transcription. The data suggest that phosphorylation of UBF by CKII may play an important role in growth dependent control of rRNA synthesis.
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PMID:The nucleolar transcription factor mUBF is phosphorylated by casein kinase II in the C-terminal hyperacidic tail which is essential for transactivation. 160 Sep 46

As a means of determining how elongating RNA polymerase responds to a protein in its path, transcription has been carried out in vitro with the purified Escherichia coli enzyme on templates associated with a sequence-specific DNA binding protein. The major RNA species generated is the length expected from RNA polymerase which has transcribed to the position of the bound protein and is unable to elongate further. The binding proteins used are two mutants of the EcoRI endonuclease which are defective in cleavage function but retain high affinity for the wild-type recognition sequence (Wright, D. J., King, K., and Modrich, P. (1989) J. Biol. Chem. 264, 11816-11821). Blockage of RNA polymerase occurs on linear and circular templates and, although efficient with both proteins, is more effective for the EcoRI derivative with the slower dissociation rate. The protein-blocked transcription complexes are stable over time and remain in an active form, resuming elongation when the blocking protein is displaced by an increase in ionic strength. These paused ternary complexes, if treated with the termination factor rho, undergo release. The 3' ends of the blocked-length RNAs from DNAs of distinct sequences reveal that the ternary complexes are positioned at a constant distance from the protein block, 14 nucleotides upstream of the EcoRI recognition sequence. This information is combined with exonuclease III footprinting data to position the 3' end of the nascent RNA chain in the ternary complex quite near (approximately 7 nucleotides) the leading edge of RNA polymerase.
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PMID:Elongation by Escherichia coli RNA polymerase is blocked in vitro by a site-specific DNA binding protein. 169 18

A sequence 30 bp downstream from the start site of the Drosophila melanogaster retrotransposon mdg1 is shown to be responsible for correct and precise initiation of mdg1 RNA synthesis in combination with the RNA start-site sequence TCAGTT. A sequence-specific DNA binding protein is demonstrated to interact with the +30 sequence, and the efficient binding of this factor is necessary for in vivo transcriptional activity of the plasmid constructs containing mdg1 promoter fragments. The nucleotides -8/+34 of mdg1 represent a minimal promoter which is able to provide correct initiation of transcription by RNA polymerase II at basal levels. A comparison with properties of some other retrotransposable elements and several developmentally regulated cellular genes allows us to conclude that together they form a specific class of RNA polymerase II promoter. This promoter class characteristically lacks upstream sequences necessary for transcription initiation, such as TATA boxes, but requires a specific downstream promoter element within 40 bp downstream of the RNA start site. The level of transcription can, however, be modulated by upstream regulatory elements. The identified sequence-specific downstream initiation factor may be responsible for transcription initiation on promoters of some genes which belong to this class.
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PMID:Properties of promoter regions of mdg1 Drosophila retrotransposon indicate that it belongs to a specific class of promoters. 170 22

We have attempted to determine the site of termination of transcription of ribosomal RNA in the yeast, Saccharomyces cerevisiae. While a quantitative description of the termination sites of RNA polymerase I is not possible using presently available methods, we conclude that transcription of most molecules continues through a large portion of the adjacent enhancer region. There are two potential termination sites within the enhancer, one of which is near the binding site of the DNA binding protein REBI. In addition there is an apparently fail-safe termination site approximately 950 nucleotides beyond the 3' end of 35S ribosomal precursor RNA. Processing at the end of 35S RNA influences the choice of downstream termination site. Conversely downstream sequences also influence the site of termination.
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PMID:Termination of transcription of ribosomal RNA in Saccharomyces cerevisiae. 192 96

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