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)

In vivo, T7 DNA replication is initiated 15% of the distance from the genetic left end of the chromosome. This site, the primary origin of replication, consists of a 200-base pair (bp) intergenic segment from 14.5 to 15.0% within which are located two tandem T7 RNA polymerase promoters (phi 1.1A and phi 1.1B) followed by a 61-bp AT-rich (79% A + T) region. A fragment of T7 DNA containing the primary origin has been inserted into plasmids in order to facilitate studies on initiation in vitro. Initiation of DNA synthesis can be reconstituted using T7 RNA polymerase, T7 DNA polymerase, and T7 origin-containing plasmid DNAs. DNA synthesis is stimulated greatly by the T7 gene 4 protein, an enzyme that has helicase and primase activities. When T7 gene 4 protein is present, replication primarily yields partially replicated Y-form molecules as observed by electron microscopy. Synthesis is unidirectional and the branches of the Y-form molecules are uniform in size, with the branch point of the Y located at the origin. Using restriction enzyme analysis, DNA synthesis has been shown to proceed in the same direction (rightward with respect to the T7 genetic map) as transcription from the two promoters located at the origin. Initiation of DNA synthesis in the opposite direction requires the addition of a single-stranded DNA-binding protein (Fuller, C.W., and Richardson, C.C. (1985) J. Biol. Chem. 260, 3197-3206). The initial products of DNA synthesis have been analyzed by polyacrylamide gel electrophoresis. These DNAs have 10 to 60 ribonucleotides covalently linked to their 5' termini. These RNA primers arise by transcription from each of the two promoters, phi 1.1A and phi 1.1B, located within the primary origin.
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PMID:Initiation of DNA replication at the primary origin of bacteriophage T7 by purified proteins. Site and direction of initial DNA synthesis. 298 51

Phage T7 DNA polymerase consists of a 1:1 complex of the viral T7 gene 5 protein and the host cell thioredoxin. A 3.25-kilobase T7 DNA fragment containing the complete coding sequence of gene 5, and the nearby genes 4.7 and 5.3, was cloned in the BamHI site of the plasmid pBR322. Transformation of the thioredoxin-negative (trxA-) Escherichia coli strain BH215 with the recombinant plasmid pRS101 resulted in large overproduction of gene 5 protein corresponding to a level about 60-fold higher than in T7-infected cells. Transcription of gene 5 probably originates from a previously unknown E. coli RNA polymerase promoter located immediately upstream of the structural gene. Contrary to expectation, pRS101 could be maintained also in E. coli trxA+ cells despite the in vivo formation of active T7 DNA polymerase. However, the expression of gene 5 was lower by a factor of 5-10 than in trxA- cells. Since the plasmid copy number in the two strains was the same, a gene dosage effect can be excluded. The observed difference suggests an autoregulatory interaction of T7 DNA polymerase holoenzyme on the expression of T7 gene 5. The trxA- strain BH215/pRS101 is an excellent source of gene 5 protein and T7 DNA polymerase. After in vitro reconstitution of holoenzyme by addition of excess thioredoxin, highly active T7 DNA polymerase was purified to homogeneity by a simple antithioredoxin immunoadsorbent chromatography technique.
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PMID:Bacteriophage T7 DNA polymerase: cloning and high-level expression. 299 84

Escherichia coli strains containing mutations in various deoxyribonucleic acid synthesis cistrons have been tested for their ability to support bacteriophage N4 growth and, specifically, N4 DNA synthesis. N4 DNA synthesis is independent of the activity of the products of the E. coli dnaA, dnaB, dnaC, dnaE, dnaG, and rep genes. In contrast, N4 DNA replication requires the products of the dnaF, (ribonucleotide reductase) and lig (DNA ligase) genes of E. coli. N4 DNA replication, specifically processing of short DNA fragments requires the 5'-3' exonuclease activity of the polA gene product. However, its DNA polymerizing activity is not required. In addition, the sensitivity of N4 DNA synthesis to inhibitors or temperature-sensitive mutants of E. coli DNA gyrase suggests that this activity is required for N4 DNA synthesis. To date, we have found five N4 gene products required for N4 DNA replication: dbp (a single-stranded DNA binding protein), dnp (a DNA polymerase), dns (unknown function), vRNAp (the N4 virion-associated, DNA-dependent RNA polymerase) and exo (a 5'-3' exonuclease).
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PMID:Host and phage-coded functions required for coliphage N4 DNA replication. 300 44

Six mutations, impairing DNA polymerase of E. coli in combination with the wild type gene for rho factor or ts-mutation rho 15 have been studied in relation to the expression of seven operons having different types of regulation. The expression of genes for glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase is shown to be constitutive and resistant to mutationally altered RNA polymerase and rho factor. The expression of genes for adenine phosphoribosyltransferase and of deo operon is regulated by rho dependent attenuators with attenuation being lifted incomplete medium. Mutation rho 15 decreases the level of enzymes of thr and lac operons independent of mRNA levels of these operons. Mutation rho 15 effect on posttranscriptional level is modified by mutations damaging RNA polymerase. The data obtained suppose RNA polymerase to affect all stages of realization of genetic information, beginning with promoter recognition and RNA synthesis and including the protein synthesis on mRNA.
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PMID:[Effect of mutation changes in RNA-polymerase and transcription termination factor rho on expression of various operons in E. coli]. 302 82

Bacteriophage T7 DNA replication is initiated at a site 15% of the distance from the genetic left end of the chromosome. This primary origin contains two tandem T7 RNA polymerase promoters (phi 1.1A and phi 1.1B) followed by an A + T-rich region. When the primary origin region is deleted replication initiates at secondary origins. We have analyzed the ability of plasmids containing cloned fragments of T7 to replicate after infection of Escherichia coli with bacteriophage T7. All cloned T7 fragments that support plasmid replication contain a T7 promoter but a T7 promoter alone is not sufficient for replication. Replication of plasmids containing the primary origin is dependent on T7 DNA polymerase and gene 4 protein (helicase/primase) and a portion of the A + T-rich region. The other T7 fragments that support plasmid replication after T7 infection are promoter regions phi OR, phi 13 and phi 6.5 (secondary origins). When both the primary and secondary origins are present simultaneously on compatible plasmids, replication of each is temporally regulated. Such regulation may play a role during T7 DNA replication.
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PMID:Initiation of DNA replication at cloned origins of bacteriophage T7. 306 20

Interferons (IFNs) have been shown to suppress the growth of both normal and malignant cells. We examined the effect of gene-cloned IFN-alpha and IFN-gamma on the in vitro activities of human, calf, or rat DNA polymerases. IFN-alpha strongly inhibited the reactions of DNA polymerase alpha and beta at apparent Ki values of 1.25 and 0.35 x 10(5) antiviral units/ml, respectively, but inhibited DNA polymerase gamma only slightly. IFN-gamma inhibited the reaction of DNA polymerase alpha more strongly (Ki, 1.2 x 10(4) units/ml) than IFN-alpha, but not that of DNA polymerase beta. On the other hand, neither IFN-alpha nor IFN-gamma inhibited the reactions of DNA polymerase I from Escherichia coli, Klenow fragment, T-4 DNA polymerase, and RNA polymerase. The fact that Ki values for IFN-alpha of DNA polymerase from calf thymus, human leukemic cells, and rat liver were similar suggests the absence of species specificity among animals with regard to the inhibition of DNA polymerases by IFNs. These results indicate that DNA polymerase may be one of the targets of the action of IFNs.
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PMID:Inhibition of mammalian DNA polymerases by recombinant alpha-interferon and gamma-interferon. 311 59

The RNA polymerase gene of bacteriophage T7 has been cloned into the plasmid pBR322 under the inducible control of the lambda PL promoter. After induction, T7 RNA polymerase constitutes 20% of the soluble protein of Escherichia coli, a 200-fold increase over levels found in T7-infected cells. The overproduced enzyme has been purified to homogeneity. During extraction the enzyme is sensitive to a specific proteolysis, a reaction that can be prevented by a modification of lysis conditions. The specificity of T7 RNA polymerase for its own promoters, combined with the ability to inhibit selectively the host RNA polymerase with rifampicin, permits the exclusive expression of genes under the control of a T7 RNA polymerase promoter. We describe such a coupled system and its use to express high levels of phage T7 gene 5 protein, a subunit of T7 DNA polymerase.
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PMID:A bacteriophage T7 RNA polymerase/promoter system for controlled exclusive expression of specific genes. 315 76

The T7 chromosome is a double-stranded linear DNA molecule flanked by direct terminal repeats or so-called terminal redundancies. Late in infection bacteriophage T7 DNA accumulates in the form of concatemers, molecules that are comprised of T7 chromosomes joined in a head to tail arrangement through shared terminal redundancies. To elucidate the molecular mechanisms of concatemer processing, we have developed extracts that process concatemeric DNA. The in vitro system consists of an extract of phage T7-infected cells that provides all T7 gene products and minimal levels of endogenous concatemeric DNA. Processing is analyzed using a linear 32P-labeled substrate containing the concatemeric joint. T7 gene products required for in vitro processing can be divided into two groups; one group is essential for concatemer processing, and the other is required for the production of full length left-hand ends. The products of genes 8 (prohead protein), 9 (scaffolding protein), and 19 (DNA maturation) along with gene 18 protein are essential, indicating that capsids are required for processing. In extracts lacking one or more of the products of genes 2 (Escherichia coli RNA polymerase inhibitor), 5 (DNA polymerase), and 6 (exonuclease), full length right-hand ends are produced. However, the left-hand ends produced are truncated, lacking at least 160 base pairs, the length of the terminal redundancy. Gene 3 endonuclease, required for concatemer processing in vivo, is not required in this system. Both the full length left- and right-hand ends produced by the processing reaction are protected from DNase I digestion, suggesting that processing of the concatemeric joint substrate is accompanied by packaging.
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PMID:Processing of concatemers of bacteriophage T7 DNA in vitro. 329 44

A minimal mechanism is proposed which describes the transcriptional and translational processes for four phage proteins (RNA polymerase, DNase, primase and DNA polymerase) involved in T3/T7 DNA replication. Phage DNA replication is also included. It is shown how lag times may be incorporated into a kinetic mechanism. The distinct three-stage transport of phage DNA into the bacterial host (E. coli) is considered. DNA transport is assumed to be rate-determining for the transcription of class I and II proteins. Transcriptional and translational lag times have been calculated on the basis of available gene mapping of T7 phages. The kinetic behavior of T7 and T3 phage infection is practically identical. The hydrolysis of bacterial DNA by phage DNase (endonculease and exonuclease) as well as the subsequent phosphorylation to the deoxymononucleoside triphosphates are assumed to be rate-determining in phage DNA replication. Good agreement with experiment is obtained in our computer simulations.
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PMID:Computer simulation of T3/T7 phage infection using lag times. 330 Aug 7

Racemic carbocyclic analogues of dTTP [(+/-)-C-dTTP] and its ribo counterpart, 5-methyl-UTP [(+/-)-C-m5UTP] were synthesized and examined, in comparison with dTTP and UTP (and m5UTP), as potential substrates of E. coli DNA and RNA polymerases, respectively. Unexpectedly, only a very low (terminal) incorporation of C-dTMP into DNAs of different structure was observed, C-dTTP did not serve as a substrate for chain elongation by the Klenow DNA polymerase. Inhibition of DNA replication was, however, observed in the presence of (+/-)-C-dTTP. The UTP analogue, (+/-)-C-m5UTP proved neither a substrate nor an inhibitor of the RNA polymerase enzyme.
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PMID:Carbocyclic analogues of dTTP and UTP: properties in polymerase enzyme-catalyzed reactions. 332 Sep 75

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