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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)

Coumermycin A1, a specific inhibitor of DNA gyrase, differentially changes the spectrum of proteins synthesized in wild type E. coli cells but has no effect on the protein spectrum in mutant cells with coumermycin-resistant DNA gyrase. The rpoB265 mutation affecting RNA polymerase decreases the coumermycin A1-sensitivity of bacteria while the rpoC3 mutation increases it. The interaction of wild type and mutant RpoB265 RNA polymerases with ColEl plasmid DNA in vitro is differently affected by DNA supercoiling. No such differences are observed in the case of RpoC3 RNA polymerase. The results suggest that template supercoiling may have a substantial effect on transcription in vivo, an effect which, in some cases, depends on the properties of RNA polymerase.
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PMID:DNA supercoiling and transcription in Escherichia coli: influence of RNA polymerase mutations. 23 26

A DNA-dependent RNA polymerase has been purified from disrupted virions of the Escherichia coli bacteriophage N4. The RNA polymerase is phage-coded and is required for class I N4 RNA synthesis, which is defined as RNA synthesized in vivo in the absence of post-infection protein synthesis. A polypeptide of molecular weight 350,000 is detected when the purified enzyme is analyzed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. N4 RNA polymerase requires denatured DNA as a template in vitro and shows a strong preference for denatured N4 DNA. With this template, transcription is asymmetric. The RNA product is complementary to only the H strand of N4 DNA. Furthermore, only class I N4 RNA is synthesized. In vivo transcription by the N4 virion RNA polymerase is inhibited by coumermycin. This result suggests that the activity of E. coli DNA gyrase, an enzyme that introduces negative supertwists into DNA, is required for N4 transcription.
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PMID:Novel template requirements of N4 virion RNA polymerase. 35 50

Coliphage N4 is a double-stranded DNA virus that requires the sequential activity of three different RNA polymerases during infection. The N4 virion RNA polymerase, which is carried in the virion and is injected with the DNA at the start of infection, is responsible for the synthesis of N4 early RNAs. In vitro, the virion RNA polymerase can transcribe double-stranded N4 DNA accurately and efficiently but only when the DNA is denatured. We have shown previously that the activity of DNA gyrase is required for in vivo early N4 transcription. We report here that Escherichia coli single-stranded DNA-binding protein (SSB) is also required for N4 early transcription. In vitro, linear or relaxed templates cannot be activated by SSB; however, supercoiled template and SSB allow the virion polymerase to recognize its promoters on duplex DNA and activate transcription. The effects of supercoiling are limited to transcript initiation and are not required for transcript elongation. The activation is specific for SSB; no other single-stranded DNA-binding proteins can substitute. Therefore, SSB is one of a small number of proteins that function to stimulate both replication and transcription. The basis for the specificity of SSB, the mechanism of transcriptional activation by SSB and template supercoiling, and their role in the N4 transcriptional program during development are discussed.
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PMID:Escherichia coli single-stranded DNA-binding protein is a supercoiled template-dependent transcriptional activator of N4 virion RNA polymerase. 138 90

We report here the isolation, sequence analysis, structure, and expression of the gene encoding the largest subunit of RNA polymerase III (RPIII) from Plasmodium falciparum. The P. falciparum RPIII gene consists of 5 exons and 4 introns, is expressed in all of the asexual erythrocytic stages of the parasite as a 8.5-kb mRNA, and is present in a single copy on chromosome 13. The predicted 2339 amino acid residue RPIII subunit contained 5 regions that were conserved between different eukaryotic RPIII subunits, and 4 variable regions that separated the conserved regions. Three of the variable regions were greatly enlarged in comparison to the corresponding variable regions in other RPIII subunits. Variable region C' represented nearly one-third of the P. falciparum RPIII subunit (750 amino acid residues), included a unique repeated decapeptide sequence, and had some homology with yeast DNA topoisomerase II. Noteworthy amino acid sequences and structures were identified in both the conserved regions and in the enlarged variable regions, and their possible role(s) as domains that regulate RPIII enzyme activity is discussed.
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PMID:Characterization of the gene encoding the largest subunit of Plasmodium falciparum RNA polymerase III. 165 54

We have constructed and analyzed an in vitro system that will efficiently replicate plasmid RSF1010 and its derivatives. The system contains a partially purified extract from E.coli cells and three purified RSF1010-encoded proteins, the products of genes repA, repB (or mobA/repB), and repC. Replication in this system mimics the in vivo mechanism in that it (i) is initiated at oriV, the origin of vegetative DNA replication, (ii) proceeds in a population of plasmid molecules in both directions from this 396-base-pair origin region, and (iii) is absolutely dependent on the presence of each of the three rep gene products. In addition, we find that E.coli DNA gyrase, DnaZ protein (gamma subunit of poIIII holoenzyme) and SSB are required for in vitro plasmid synthesis. The bacterial RNA polymerase, the initiation protein DnaA, and the primosomal proteins DnaB, DnaC, DnaG and DnaT are not required. Furthermore, the replicative intermediates seen in the electron microscope suggest that replication in vitro begins with the simultaneous or non-simultaneous formation of two displacement loops that expand for a short stretch of DNA toward each other, and form a theta-type structure when the two displacing strands pass each other.
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PMID:Plasmid RSF1010 DNA replication in vitro promoted by purified RSF1010 RepA, RepB and RepC proteins. 185 52

In the usual metabolic control theory, the concentrations of enzymes are considered to be parameters rather than variables, i.e., they remain constant as the system relaxes to a new steady state. They can only be reset by interventions. This type of control analysis is useful for understanding principles of metabolic control, and for understanding metabolic changes that are too quick or in too limited a metabolic system to involve changes in gene expression. In actual living systems, metabolic changes are often accompanied by changes in gene expression. In this contribution we shall illustrate how metabolic control analysis is enriched when gene expression is variable. To discuss the new principles emerging in control analysis with variable gene expression, we shall first discuss theoretical model systems. In the first, the number of genes is fixed, but the concentrations of mRNA and enzymes are determined by the activities of RNA polymerase, RNAases, ribosomes and proteases. In a second, there is feedback repression by a metabolite at the level of translation. New coefficients quantifying the strength of regulatory loops will be defined. Also coefficients that indicate to what extent these regulatory strengths themselves are controlled by system parameters, are defined and provided with a summation theorem. The experimental model system we employ, addresses the phenomenon that in prokaryotes, transcription rates are influenced by the extent of supercoiling of the DNA. This includes the transcription of the genes encoding the two enzymes (DNA gyrase and topoisomerase I) involved in the regulation of DNA supercoiling. In vitro the activity of DNA gyrase is influenced by the hydrolytic free energy of ATP. We shall present experimental evidence that the cellular free-energy state influences DNA supercoiling. We shall also discuss experiments inspecting the effect of active transcription on active DNA supercoiling. Also this system will be analyzed in terms of the control analysis with variable gene expression; here the four hierarchical levels (DNA, RNA, enzymes, metabolites) interact, adding complexity to the control analysis.
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PMID:Control of DNA structure and gene expression. 196 56

Transcription of the fibroin gene can be reconstituted with partially purified components from HeLa cells. Transcription factors IIB, IID, and IIE and RNA polymerase II are required for accurate initiation of transcription. Linear and relaxed closed circular DNA show a similar level of template activity. However, transcription of closed circular DNA is stimulated when negative supercoils are introduced by the addition of DNA topoisomerase II and supercoiling factor purified from the posterior silk gland of Bombyx mori. Dissection of transcription into pre- and postinitiation steps by the use of Sarkosyl reveals that DNA supercoiling promotes formation of a preinitiation complex. Furthermore, order of addition experiments suggest that DNA supercoiling facilitates a functional binding of transcription factor IID to the promoter.
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PMID:Negative supercoiling of DNA facilitates an interaction between transcription factor IID and the fibroin gene promoter. 199 62

DNA containing the plasmid origin of bacteriophage P1 is replicated in vitro by a protein fraction prepared from uninfected Escherichia coli supplemented with purified P1 RepA protein. It has previously been shown that the reaction required the E. coli DnaA initiator protein, the DnaB helicase, DnaC protein, RNA polymerase, and DNA gyrase. I show here that three E. coli heat shock proteins, DnaJ, DnaK, and GrpE, are directly involved in P1 plasmid replication. Purified DnaJ, DnaK, and GrpE proteins were required to stimulate P1 plasmid ori DNA-dependent replication in in vitro complementation assays in which the host protein fractions were prepared from cells mutated in the corresponding gene. I have also found that the DnaJ and RepA proteins form a complex. This complex exists in crude cell extracts and can be isolated as a molecular species of about 160,000 Da containing one dimer of DnaJ protein and one dimer of RepA. The complex can also be reconstituted by mixing purified DnaJ and RepA proteins. These results imply that the DnaJ-RepA complex, DnaK, and GrpE are directly involved in P1 plasmid replication.
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PMID:Three Escherichia coli heat shock proteins are required for P1 plasmid DNA replication: formation of an active complex between E. coli DnaJ protein and the P1 initiator protein. 218 45

DNA can form structures other than the Watson-Crick double helix. The potential contributions to gene regulation from one such structure have been investigated by assembling a promoter capable of adopting cruciform base-pairing. Transcription from this promoter by RNA polymerase in vitro was repressed as the cruciform was extruded by increasing negative DNA supercoiling. Transcription in vivo was induced as supercoiling was relaxed by growth in conditions that inhibit DNA gyrase. A DNA conformational change is therefore capable of regulating the initiation of transcription.
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PMID:An E. coli promoter that regulates transcription by DNA superhelix-induced cruciform extrusion. 245 17

Mechanisms that could operate to initiate pBR322 DNA replication in the absence of RNase H and DNA polymerase I are described. Two different pathways leading to extensive unwinding of pBR322 DNA have been observed under DNA replication reaction conditions in vitro. In the presence of RNA polymerase and DNA gyrase, specifically initiated RNA II (the leading-strand primer precursor) can form an RNA-DNA hybrid with the template that starts just upstream of the origin of DNA replication and continues for about 3 kilobases. Subsequent digestion of the RNA in this RNA-pBR322 DNA hybrid results in the formation of a highly unwound DNA termed form I. If DNA gyrase is absent during the RNA polymerase-catalyzed elongation of RNA II, a stable RNA-pBR322 DNA hybrid can still form that is localized to the origin region of the genome. Formation of this hybrid activates the primosome assembly site present on the lagging-strand DNA template, by displacing it to a single-stranded conformation, thereby allowing preprimosome assembly. Once assembled, the DNA helicase activity of the preprimosome, in the presence of the single-stranded DNA binding protein and DNA gyrase but in the absence of any further transcription, can also result in extensive unwinding of pBR322 DNA. The product of this reaction, form I DNA, is more unwound than form I DNA. The formation of both form I and form I DNA is inhibited by the presence of excess RNA I, as well as by RNase H at concentrations sufficient to catalyze the normal processing of RNA II required for initiation of leading-strand DNA synthesis. These results suggest that RNA II-pBR322 DNA hybrid formation is essential to permit preprimosome assembly during pBR322 DNA replication under conditions where both RNase H and DNA polymerase I are absent.
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PMID:Transcriptional activation of pBR322 DNA can lead to duplex DNA unwinding catalyzed by the Escherichia coli preprimosome. 247 95

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