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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)

Studies with yeast DNA topoisomerase mutants indicate that neither topoisomerase I nor II appears to be essential for transcription by RNA polymerase II. However, plasmids carrying transcriptionally active genes are found to be extremely negatively supercoiled when isolated from mutants lacking topoisomerase I. Supercoiling occurs during transcriptional elongation rather than during transcriptional activation. It takes place in the absence of topoisomerase I and does not seem to be dependent on topoisomerase II since it can occur at the nonpermissive temperature in a top1-top2 ts mutant. Whether this change in linking number is due to an unusual form of topoisomerase II or whether it is due to a new enzyme has yet to be determined. The results suggest that topoisomerase I is normally required to relax transcriptionally induced supercoils. A model is discussed which considers the role of topoisomerases in the movement of RNA polymerase along the DNA template.
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PMID:Transcription-dependent DNA supercoiling in yeast DNA topoisomerase mutants. 284 Feb 7

The putative structural gene encoding the vaccinia virus type I DNA topoisomerase (EC 5.99.1.2) was expressed in Escherichia coli under the control of a bacteriophage T7 promoter. Provision of T7 RNA polymerase resulted in the accumulation to high level of a Mr = 33,000 type I topoisomerase with the properties of the vaccinia enzyme. A simple purification scheme yielded approximately 8 mg of recombinant vaccinia topoisomerase from 400 ml of bacteria. DNA unwinding by the enzyme was stimulated by magnesium, manganese, calcium, cobalt, and spermidine, but inhibited by copper and zinc. Like eukaryotic cellular type I topoisomerases, but unlike the prokaryotic counterpart, the recombinant topoisomerase relaxed positively and negatively supercoiled DNA. The viral topoisomerase I was, however, resistant to the effects of camptothecin, a drug that specifically inhibits cellular type I topoisomerases.
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PMID:Characterization of vaccinia virus DNA topoisomerase I expressed in Escherichia coli. 284 43

RNA polymerase I preparations purified from a rat hepatoma contained DNA topoisomerase activity. The DNA topoisomerase associated with the polymerase had an Mr of 110,000, required Mg2+ but not ATP, and was recognized by anti-topoisomerase I antibodies. When added to RNA polymerase I preparations containing topoisomerase activity, anti-topoisomerase I antibodies were able to inhibit the DNA relaxing activity of the preparation as well as RNA synthesis in vitro. RNA polymerase II prepared by analogous procedures did not contain topoisomerase activity and was not recognized by the antibodies. The topoisomerase I: polymerase I complex was reversibly dissociated by column chromatography on Sephacryl S200 in the presence of 0.25 M (NH4)2SO4. Topoisomerase I was immunolocalized in the transcriptionally active ribosomal gene complex containing RNA polymerase I in situ. These data indicate that topoisomerase I and RNA polymerase I are tightly complexed both in vivo and in vitro, and suggest a role for DNA topoisomerase I in the transcription of ribosomal genes.
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PMID:Association of DNA topoisomerase I and RNA polymerase I: a possible role for topoisomerase I in ribosomal gene transcription. 285 18

Previously, we have shown that DNA in a small fraction (2-5%) of SV40 minichromosomes was torsionally strained and could be relaxed by treating minichromosomes with topoisomerase I. This fraction was enriched with endogeneous RNA polymerase II (Luchnik et al., 1982, EMBO J., 1, 1353). Here we show that one and the same fraction of SV40 minichromosomes is hypersensitive to DNAase I and is relaxable by topoisomerase I. Moreover, this fraction completely loses its hypersensitivity to DNAase I upon relaxation. The possibility that this fraction of minichromosomes can be represented by naked DNA is ruled out by the results of studying the kinetics of minichromosome digestion by DNAase I in comparison to digestion of pure SV40 DNA and by measuring the buoyant density of SV40 chromatin in equilibrium CsCl gradient. Our data obtained with SV40 minichromosomes may be relevant to the mechanism responsible for DNAase I hypersensitivity in the loops or domains of cellular chromatin.
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PMID:DNAaseI-hypersensitive minichromosomes of SV40 possess an elastic torsional strain in DNA. 298 17

Replication of plasmids that depend on the 245-base-pair origin of the Escherichia coli chromosome (oriC) requires many purified proteins that (i) direct initiation to oriC (e.g., dnaA protein), (ii) influence initiations elsewhere (e.g., auxiliary proteins), and (iii) prime and extend DNA chains (e.g., priming and synthesis proteins). For the RNA priming and initiation of new DNA chains, the requirements for both primase and RNA polymerase (RNA pol) [Kaguni, J. M. & Kornberg, A. (1984) Cell 38, 183-190] have been further analyzed. Depending on the levels of auxiliary proteins (topoisomerase I and protein HU), three priming systems can operate: primase alone, RNA pol alone, or both combined. At low levels of auxiliary proteins, primase alone sustains an effective priming system. At higher levels, primase action is blocked, but RNA pol alone can initiate replication, albeit feebly; at these high levels of auxiliary proteins, primase and RNA pol act synergistically. When RNA pol is stalled by an inhibitor or lack of a ribonucleoside triphosphate, primase action is also inhibited. Based on these and other data [van der Ende, A., Baker, T. A., Ogawa, T. & Kornberg, A. (1985) Proc. Natl. Acad. Sci. USA 82, in press], RNA pol can counteract inhibition by auxiliary proteins and thus activate the origin for the priming by primase of the leading strand of the replication fork.
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PMID:Initiation of enzymatic replication at the origin of the Escherichia coli chromosome: contributions of RNA polymerase and primase. 298 33

The replication of plasmid pBR322 DNA has been reconstituted with purified proteins from Escherichia coli. Initiation of the leading-strand requires RNA polymerase holoenzyme, DNA polymerase I, RNase H, and DNA gyrase. Initiation of the lagging-strand requires the primosomal proteins (the dnaB, dnaC, and dnaG proteins, replication factor Y (protein n') and proteins i, n, and n") and the single-stranded DNA binding protein. DNA polymerase III holoenzyme is required for extensive elongation of the nascent DNA chains. The products of this replication reaction are primarily nonsegregated daughter molecules. However, the addition of small amounts of soluble extract from E. coli results in the completion and segregation of these molecules to give mature form I DNA, suggesting that additional factors are required for this process. Topoisomerase I is necessary to make the replication system specific for pBR322 DNA as a template, indicating that the linking number of the DNA, determined by an equilibrium between the opposing activities of topoisomerase I and DNA gyrase, plays a crucial role in determining the reactivity of the DNA molecule toward initiating DNA replication. The function of the proteins involved in the replication of this closed-circular, double-stranded, superhelical DNA is discussed.
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PMID:Replication of pBR322 DNA in vitro with purified proteins. Requirement for topoisomerase I in the maintenance of template specificity. 299 Dec 40

The in vivo distribution of topoisomerase I on specific DNA sequences is determined at high resolution in Drosophila cells using a photo-crosslinking method. Topoisomerase I-DNA adducts are generated by irradiation of intact cells with UV light and then purified by immunoprecipitation with antibody to topoisomerase I. Analyses of the DNA sequences crosslinked to topoisomerase I by blot-hybridization with appropriate DNA probes indicate that topoisomerase I is concentrated on transcribed regions and not on nontranscribed flanking sequences. Like RNA polymerase II, topoisomerase I is recruited to heat-shock genes during the heat-shock response. However, topoisomerase I and RNA polymerase II can interact independently with the transcribed region because different ratios of topoisomerase I and RNA polymerase II are crosslinked to the highly transcribed hsp70 gene and the moderately transcribed copia genes. We hypothesize that topoisomerase I allows topological changes in DNA that are required for transcription.
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PMID:Topoisomerase I interacts with transcribed regions in Drosophila cells. 300 35

In the presence of 5% dimethylsulfoxide, 2.5 fold increase in vitro RNA synthesis rate by E. coli RNA polymerase was observed as superhelical pBR322 DNA was used as template. The effect of DMSO on DNA conformation was studied by: [i] measuring the dissociation constant of EtBr-DNA complex and the maximum EtBr binding site of EtBr in DNA which changed from 7.52 X 10(-7) M and 0.18 site per nucleotide to 9.61 X 10(-7) M and 0.156 site per nucleotide respectively when 10% DMSO was supplemented; and [ii] the increase of average linking number of pBR322 DNA in DMSO solution with topoisomerase I reaction. These results suggest that the stimulation of RNA synthesis may be caused by the easier initiation and elongation of RNA synthesis at some locally loosen regions of DNA affected by another torsionally more twisted counterpart regions in the DMSO microenvironment.
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PMID:The effect of DMSO on natural DNA conformation in enhancing transcription. 304 3

The highly defective rho-15 mutant of Escherichia coli produces plasmid DNA that is 22% less negatively supercoiled than DNA from an isogenic wild-type strain (J. S. Fassler, G. F. Arnold, and I. Tessman, Mol. Gen. Genet. 204:424-429, 1986). We extended our measurements of plasmid superhelicity to additional rho mutants and to strains containing mutations that suppress rho transcription termination defects; the suppressor mutations were in the rpoB and the rho genes. The superhelicity of plasmid DNA was reduced by 11 and 10%, respectively, in the rho-702 and rho-201 mutants, both of which are less defective in Rho-mediated transcription termination than rho-15. Plasmid superhelicity was restored in all the suppressed rho mutants; in one rpoB mutant, plasmid DNA was even more negatively supercoiled than in rpoB+ cells, whether in a rho+ or rho mutant background. Suppression of rho mutants enabled them to maintain plasmids that could not be maintained in the mutants in the absence of the suppressor mutations. The results indicate that in addition to DNA gyrase, topoisomerase I, and Rho, RNA polymerase is also a determinant of DNA superhelicity, and its effect is modified by the Rho protein. We propose that Rho may increase the degree of DNA unwinding by the transcription complex, possibly at transcription termination sites.
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PMID:Regulation of DNA superhelicity by rpoB mutations that suppress defective Rho-mediated transcription termination in Escherichia coli. 304 90

A crude soluble enzyme system capable of authentic replication of a variety of oriC plasmids has been replaced by purified proteins constituting three functional classes: initiation proteins (RNA polymerase, dnaA protein, gyrase) that recognize the oriC sequence and presumably prime the leading strand of the replication fork; replication proteins (DNA polymerase III holoenzyme, single-strand binding protein, primosomal proteins) that sustain progress of the replication fork; and specificity proteins (topoisomerase I, RNAase H, protein HU) that suppress initiation of replication at sequences other than oriC, coated with dnaA protein. Protein HU and unidentified factors in crude enzyme fractions stimulate replication at one or more stages. Replication has been separated temporally and physically into successive stages of RNA synthesis and DNA synthesis.
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PMID:Replication initiated at the origin (oriC) of the E. coli chromosome reconstituted with purified enzymes. 608 63

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