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)

When closed circular SV40 DNA containing 58 negative superhelical turns is used as a template for RNA synthesis with Escherichia coli RNA polymerase, a fraction of the RNA product remains complexed with the DNA. The RNA in the complex is resistant to ribonuclease in high salt, and the Tm indicates that it is hydrogen bonded to the DNA. The mole ratio of RNA to DNA nucleotides in the complex ranges from 0.01 to 0.08; the RNA ranges in length from 80 to 600 nucleotides. The formation of the complex is dependent on the circular DNA being topologically underwound since no complex is formed when closed circular DNA containing zero superhelical turns is used as the template. The DNA-RNA complex can serve as a primer-template combination for in vitro DNA synthesis by E. coli DNA polymerase I. After synthesis with (alpha-32P)-labeled deoxyribonucleoside triphosphates followed by alkaline hydrolysis, the isolation of 32P-labeled ribonucleotides is evidence for a covalent linkage between the RNA and the DNA synthesized. During the in vitro DNA synthesis, the template is nicked at a low rate, and the nicked molecules support extensive DNA synthesis. This observation indicates that only limited synthesis can occur on unnicked molecules possibly owing to the topological constraints against unwinding of the helix. Possible models for in vivo priming of double-stranded DNA by E. coli RNA polymerase are discussed.
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PMID:Priming of superhelical SV40 DNA by Escherichia coli RNA polymerase for in vitro DNA synthesis. 16 2

Metaphase chromosomes from the Chinese hamster cell line M3-1 were separated by means of a flow sorter. Two chromosome fractions were used for this study: A, which consisted of 95% pure chromosome no. 1, and B, which was 90% pure chromosome no. 2. The DNA of 10(6) chromosomes of each type was purified, and a 125I-cRNA transcript was synthesized in a reaction containing E. coli RNA polymerase and carrier-free 125I-CTP (1.7 Ci/mumole). The cRNA product synthesized with template DNA from 10(5) sorted chromosomes contained more than 10(6) dpm. The electrophoretic mobility profiles of the cRNAs on 7.5% SDS acrylamide gels demonstrated that more than 50% of the ribo-polymers were equal to or longer than marker E. coli met-tRNAf. In hybridization reactions 21% and 17% of the transcripts from Chinese hamster whole cell and sorted chromosome DNA hybridized to Chinese hamster DNA and did not hybridize significantly over background in reactions containing calf DNA at Crt values of 1.3 and 1.9 x 10(2) mole sec/l. Labelled cRNAs transcribed from the DNA of sorted chromosomes hybridized with the DNA of each sorted chromosome fractions at a Crt of 0.6 mole sec/l. This study demonstrated that the DNA can be (1) recovered from small numbers of highly purified flow sorted chromosomes, (2) used as template by E. coli RNA polymerase and (3) used to prepare a cRNA in reactions containing polymerase and carrier-free 125I-CTP to yield a product which can be employed for hybridization analysis.
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PMID:Transcription and hybridization of 125I-cRNA from flow sorted chromosomes. 42 70

The 23S rRNA gene was excised from the rrnB operon of pKK3535 and ligated into pUC19 behind the strong class III T7 promoter so that the correct 5' end of mature 23S RNA was produced upon transcription by T7 RNA polymerase. At the 3' end, generation of a restriction site for linearization required the addition of 2 adenosine residues to the mature 23S sequence. In vitro runoff transcripts were indistinguishable from natural 23S RNA in size on denaturing gels and in 5'-terminal sequence. The length and sequence of the 3' terminal T1 fragment was also as expected from the DNA sequence, except that an additional C, A, or U residue was added to 21%, 18%, or 5% of the molecules, respectively. Typical transcription reactions yielded 500-700 moles RNA per mole template. This transcript was used as a substrate for methyl transfer from S-adenosyl methionine catalyzed by Escherichia coli cell extracts. The majority (50-65%) of activity observed in a crude (S30) extract appeared in the post-ribosomal supernatant (S100). Activities catalyzing formation of m5C, m5U, m2G, and m6A residues in the synthetic transcript were observed.
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PMID:Cloning, in vitro transcription, and biological activity of Escherichia coli 23S ribosomal RNA. 219 63

In the hepatitis B virus (HBV) genome four long open reading frames (ORFs) have been found that encode the virus core, surface and polymerase proteins as well as a protein that appears to be involved in virus gene expression (X). However, all HBV genomes examined contain two addition ORFs designated ORF5 and ORF6. ORF5 is located on the same strand as the four known viral genes and is 70-100 codons in size. ORF6 is located on the DNA strand complementary to the one that encodes the other virus genes, and is approximately 210 codons in length. Both ORFs are located in the X gene region which corresponds to the 3' terminus of the linear RNA genome. Northern blot analysis identified an X region specific transcript of approximately 0.7 kb. Although this transcript may be the template for the translation of the X gene protein it may also be involved in the expression of the protein encoded by ORF5. The promoter for this transcript may consist, in part, of the 15 residue sequence GCYTGYYTTGCYCGC because this sequence is near the 5' end of the transcript, it is highly conserved among hepadnaviruses, and it contains sequences involved in RNA polymerase binding. Also, the nucleotides within this region of the hepadnavirus genome are capable of forming a stable (G = -18 kcal/mole) hairpin structure. Understanding the organization and gene expression of the X region may be crucial in expanding our knowledge on the biology of HBV.
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PMID:Organization of the X gene region of the hepatitis B virus genome. 222 61

Initiated transcription complexes were exposed to adriamycin for up to 48 h. Subsequent elongation of the transcription complex revealed the presence of a series of discrete long-lived blockage sites. The mole fraction of blocked transcripts increased linearly with reaction time, adriamycin concentration, and Fe(III) concentration. Optimal conditions for formation of the blocked transcript were 24-h reaction time, 10 microM adriamycin, and 75 microM Fe(III) ions. Nine high-intensity blocked transcripts were observed, and all correspond to transcription proceeding up to G of GpC sequences of the nontemplate strand. The presence of 75 microM Fe(III) ions enhanced the amount of transcriptional blockages by 12-15-fold. Two blocked transcripts decayed with a half-life of 0.32 and 1.9 h, and one of these exhibited 100% effective delayed termination 6 bp downstream of the original blockage site. All other blockages were unchanged after 3 h of elongation. Bidirectional transcription footprinting was used to define the physical size of the drug-induced blocking moiety as a maximum of 2 bp, and this was observed at all three GpC elements probed by RNA polymerase from both directions. The nature of the apparent covalent adducts has not yet been established but is probably a G-specific adduct deriving from a reduced form of the drug (quinone methide). Although the GpC specificity suggests an interstrand G-drug-G cross-link, these were not detected by heat denaturation and subsequent denaturing gel electrophoresis of the end-labeled promoter fragment.
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PMID:Induction of stable transcriptional blockage sites by adriamycin: GpC specificity of apparent adriamycin-DNA adducts and dependence on iron(III) ions. 238 92

We have established conditions that stabilize the interaction between RNA polymerase and the rrnB P1 promoter in vitro. The requirements for quantitative complex formation are unusual for E. coli promoters: (1) The inclusion of a competitor is required to allow visualization of a specific footprint. (2) Low salt concentrations are necessary since complex formation is salt sensitive. (3) The addition of the initiating nucleotides ATP and CTP, resulting in a low rate of dinucleotide production, is required in order to prevent dissociation of the complexes. The complex has been examined using DNAase I footprinting and filter binding assays. It is characterized by a region protected from DNAase I cleavage that extends slightly upstream of the region protected by RNA polymerase in most E. coli promoters. We find that only one mole of active RNA polymerase is required per mole of promoter DNA in order to detect filter-bound complexes. Under the conditions measured, the rate of association of RNA polymerase with rrnB P1 is as rapid as, or more rapid than, that reported for any other E. coli or bacteriophage promoter.
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PMID:Visualization and quantitative analysis of complex formation between E. coli RNA polymerase and an rRNA promoter in vitro. 305 11

Bacteriophage T3-induced RNA polymerase, upon copying its specific template, native T3 DNA, initiates RNA chains only with GTP. Denaturation of the DNA results in loss of template specificity for the polymerase. With denatured T3 DNA as template, T3 polymerase initiates RNA chains with both ATP and GTP, and the average length of the resulting RNA chains is markedly reduced. Studies of the polymerase reaction with native T3 DNA in vitro show that T3 polymerase is able to terminate RNA synthesis with the release of RNA chains from the template DNA. Polymerase is also released in the process and, acting catalytically, reinitiates new RNA chains. Many moles of RNA chains are thus formed per mole of polymerase added to the reaction mixture.
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PMID:Initiation, release, and reinitiation of RNA chains by bacteriophage-T3-induced polymerase from T3 DNA templates (E. coli-guanosine triphosphate terminus-purified polymerase). 455 May 10

In order to follow the kinetics of the initiation of transcription by the E. coli RNA polymerase, we have used the procedure of abortive initiation as described by Mc Clure (1980) (7). In place of radioactive labeling we have taken advantage of a fluorescent probe (UTP gamma ANS) to obtain fast and accurate determinations of the rate of transcription and to deduce from kinetic equations both the binding constant (KB) and the rate of isomerization (k2) which characterize the classical two-step model. This analysis was applied to the tet promoter of pBR322 in a linearized plasmid DNA and was studied in function of temperature (from 25 degrees C to 37 degrees C) and of pH (from 6 to 8.3). The association is entropy driven (delta H degrees = 29 Kcal/mole and delta S degrees = 130 e.u.). The activation energy of isomerization is 13 Kcal/mole. Both k2 and k-2 are increasing with pH. The insensitivity to pH of the KBK2 product could be tentatively explained in terms of the processive aspect of the polymerase binding to its specific site.
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PMID:A new experimental approach for studying the association between RNA polymerase and the tet promoter of pBR322. 636 39

Supercoiling of DNA is now known to have considerable effects on transcription in bacteria. By abortive initiation reaction (6) we have determined the binding constant KB and the forward rate of isomerization k2 as a function of temperature, pH and buffer for the tet promoter in a supercoiled plasmid. If the activation energy of isomerization is very similar to that obtained previously under the same conditions on a linearized plasmid (6) (respectively 21 +/- 5 kcal/mole and 13 +/- 5 kcal/mole) the supercoiling introduces very important and not well understood changes in the thermodynamic parameters of the association polymerase - promoter. Using the technique of superhelical DNA relaxation by eukaryotic topoisomerase I, we have determined the specific unwinding by RNA polymerase of the tet promoter of pBR322 (430 degrees). This unwinding differs only slightly from the mean value (470 degrees) obtained for all the promoters of pBR322.
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PMID:Effect of superhelicity on the transcription from the tet promoter of pBR322. Abortive initiation and unwinding experiments. 638 26

We initiated a survey of the Streptococcus pneumoniae genome by DNA sequence sampling. More than 9,500 random DNA sequences of approximately 500 bases average length were determined. Partial sequences sufficient to identify approximately 95% of the aminoacyl tRNA synthetase genes and ribosomal protein (rps) genes were found by comparing the database of partial sequences to known sequences from other organisms. Many genes involved in DNA replication, repair, and mutagenesis are present in S. pneumoniae. Genes for the major subunits of RNA polymerase are also present, as are genes for two alternative sigma factors, rpoD and rpoN. Many genes necessary for amino acid or cofactor biosynthesis and aerobic energy metabolism in other bacteria appear to be absent from the S. pneumoniae genome. A number of genes involved in cell wall biosynthesis and septation were identified, including six homologs to different penicillin binding proteins. Interestingly, four genes involved in the addition of D-alanine to lipoteicoic acid in other gram positive bacteria were found, even though the lipoteicoic acid in S. pneumoniae has not been shown to contain D-alanine. The S. pneumoniae genome contains a number of chaperonin genes similar to those found in other bacteria, but apparently does not contain genes involved in the type III secretion commonly observed in gram negative pathogens. The G+C content of S. pneumoniae genomic DNA is approximately 43 mole percent and the size of the genome is approximately 2.0 Mb as determined by pulsed-field gel electrophoresis. Many of the genes identified by sequence sampling have been physically mapped to the 19 different SmaI fragments derived from the S. pneumoniae genome. The database of random genome sequence tags (GSTs) provides the starting material for determining the complete genome sequence, gene disruption analysis, and comparative genomics to identify novel targets for antibiotic development.
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PMID:DNA sequence sampling of the Streptococcus pneumoniae genome to identify novel targets for antibiotic development. 953 20

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