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)

The gene for Escherichia coli rep helicase (rep protein) was subcloned in a pBR plasmid and the protein overproduced in cells transformed with the hybrid DNA. The effect of purified enzyme on strand unwinding and DNA replication was investigated by electron microscopy. The templates used were partial duplexes of viral DNA from bacteriophage fd::Tn5 and reannealed DNA from bacteriophage Mu. The experiments with the two DNA species show DNA unwinding uncoupled from replication. The single-stranded phage fd::Tn5 DNA with the inverted repeat of transposon Tn5 could be completely replicated in the presence of the E. coli enzymes rep helicase, DNA binding protein I, RNA polymerase and DNA polymerase III holoenzyme. A block in the unwinding step increases secondary initiation events in single-stranded parts of the template, as DNA polymerase III holoenzyme cannot switch across the stem structure of the transposon.
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PMID:Functional aspects of Escherichia coli rep helicase in unwinding and replication of DNA. 614 40

The bacteriophage lambda transcriptional activator protein, cII, coordinately regulates transcription from two phage promoters that control lysogenic development. We demonstrate that cII is a DNA binding protein that selectively interacts with a repeat sequence in the -35 region of the promoter. Furthermore, cII is shown to bind mainly one face of the DNA helix and to make its contacts primarily in the major groove of the DNA. RNA polymerase sees this same region from the opposite side and sandwiches the DNA helix between itself and cII.
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PMID:Bacteriophage lambda protein cII binds promoters on the opposite face of the DNA helix from RNA polymerase. 622 25

Four T7 products, DNA polymerase, gene 4 protein, RNA polymerase, and DNA binding protein, have been purified from phage-infected cells. It has been previously shown (Hinkle, D. C., and Richardson, C. C. (1975) J. Biol. Chem. 250, 5523-5529; Kolodner, R., and Richardson, C. C. (1978) J. Biol. Chem. 253, 574-584) that two T7 products, DNA polymerase and gene 4 protein, catalyze extensive synthesis on duplex T7 DNA containing single strand breaks. However, the T7 DNA polymerase purified by our procedure does not efficiently contribute in this reaction, although the preliminary evidence suggests that this enzyme may be the native form of the DNA polymerase. Such inefficient T7 DNA synthesis is greatly augmented by adding the third T7 product, namely T7 RNA polymerase. This DNA synthesis apparently requires transcription, since each of the four rNTPs must be present. The rate of synthesis is increased about 2-fold by the addition of T7 DNA binding protein. In contrast to the results obtained when DNA synthesis is initiated at single strand breaks in a duplex DNA molecule, essentially none of the DNA synthesized in the presence of T7 RNA polymerase is covalently attached to the T7 DNA template. We postulate that in this in vitro system, T7 DNA replication is initiated using an RNA primer synthesized by the T7 RNA polymerase.
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PMID:Bacteriophage T7 DNA replication in vitro. Stimulation of DNA synthesis by T7 RNA polymerase. 624 22

Simian virus 40 large T- and small t-antigens have been shown previously to share immunological determinants and common sequences and to have roles in virus-induced cell transformation. However, only large T-antigen is a DNA binding protein. Under all conditions tested, small t-antigen did not interact with DNA. Large T-antigen synthesized in infected cells bound to both native calf thymus and simian virus 40 DNAs. As its binding efficiency was less than 100%, it is likely that there are different forms of T-antigen which vary in their affinity for DNA. Large T-antigen synthesized in cell-free protein-synthesizing systems primed by simian virus 40 mRNA also bound to DNA-cellulose, whereas small t-antigen similarly synthesized in vitro did not. An 82,000-molecular-weight T-antigen polypeptide synthesized in cell-free protein-synthesizing systems primed by simian virus 40 complementary RNA transcribed in vitro from simian virus 40 DNA by Escherichia coli RNA polymerase bound efficiently to simian virus 40 DNA. As this product did not share sequences with the small t-antigen, it can be concluded that the amino-terminal portion of the T-antigen is not required for some of its specific DNA binding properties.
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PMID:DNA binding properties of simian virus 40 T-antigens synthesized in vivo and in vitro. 625 Dec 41

Cloned DNA templates were used to direct the transcription of early and late simian virus 40 (SV40) genes by a cell-free RNA-synthesizing system. Transcription by RNA polymerase II was sensitive to low levels of alpha-amanitin and completely dependent on exogenously added DNA template. RNA products of discrete lengths were efficiently synthesized when transcription was directed by DNA restriction fragments containing promoter sequences for either early or late genes of SV40. Addition of the D2 tumor antigen to the template DNA inhibited transcription originating from the SV40 early promoter. In contrast, the D2 protein had little or no effect on the transcription from SV40 or adenovirus 2 (Ad2) late promoter sequences. When a mixture of cloned DNA containing SV40 early promoter and Ad2 late promoter was used to direct RNA synthesis, the D2 protein specifically inhibited the synthesis of SV40 early genes but not that of Ad2 late sequences. The D2 DNA binding protein also had no effect on the transcription directed by SV40 mutant templates that contain an intact early promoter sequence but lack specific tumor-antigen binding sites. We have confirmed that, under the conditions of the transcription assay, the D2 protein binds and interacts specifically with its recognition sites on wild-type template DNAs but fails to bind to mutant or Ad2 DNA templates that lack sequences containing SV40 tumor-antigen binding sites. These findings provide evidence that a direct interaction between tumor antigen and its specific binding sites on DNA is the mechanism by which the SV40 A gene autoregulates its transcription.
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PMID:Regulation of simian virus 40 early transcription in vitro by a purified tumor antigen. 625 60

Escherichia coli ribonuclease H was purified to near-homogeneity and identified as the only additional factor required for initiation of in vitro Co1E1 DNA replication from the unique origin by RNA polymerase and DNA polymerase I. Both ribonuclease H activity and stimulating activity for Co1E1 DNA synthesis comigrate with the single protein band in gel electrophoresis. These two activities coincide throughout the process of purification. Some DNA synthesis takes place on covalently closed-circular DNA molecules other than Co1E1 DNA with the three purified enzymes. This DNA synthesis is suppressed by an Escherichia coli single-strand DNA binding protein and/or a high concentration of ribonuclease H. Negative superhelicity of template DNA is required for efficient primer formation. No evidence that supports involvement of ribonuclease III in initiation of Co1E1 DNA replication or its regulation was found.
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PMID:Purification of ribonuclease H as a factor required for initiation of in vitro Co1E1 DNA replication. 629 61

Three transcription units are present in the adenovirus type 2 region EII. Transcription units EIIaE and EIIaL encode the mRNA for the 72,000-dalton DNA binding protein, early and late in the lytic cycle, respectively, and transcription unit EIIb encodes the mRNA for the protein that binds to the 5' termini of adenovirus DNA. By using a cell-free transcription system in the presence of purified RNA polymerase B (or II), we have obtained specific initiation of transcription from both the EIIaE promoter, which does not contain a T-A-T-A box, and the EIIaL promoter, which does. In addition, we have identified a new EII T-A-T-A box promoter that is located close to the early non-T-A-T-A box promoter and is used both in vivo and in vitro.
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PMID:Specific in vitro initiation of transcription on the adenovirus type 2 early and late EII transcription units. 695 Mar 83

The Escherichia coli DNA binding protein FIS activates stable RNA promoters during outgrowth of cells from stationary phase. The upstream activating sequences (UASs) of these promoters contain three highly conserved FIS binding sites positioned in helical register. Neither the apparent requirement for three sites nor the mechanism of FIS-mediated activation has been established. We demonstrate here that on saturation of its three binding sites in the UAS, FIS forms a specific nucleoprotein complex which 'traps' RNA polymerase (RNAP) at the promoter of the tyrT operon. This effect is abolished by a change in helical phasing between FIS sites II and III, which impaires cooperative interactions between DNA-bound FIS dimers. The sigma 70 subunit of RNAP stimulates the formation of higher order FIS complexes, a property that is indicative of protein-protein interactions. We propose that after initiation of transcription, the released sigma 70 subunit may be recaptured by the FIS nucleoprotein 'trap' and recycled in successive rounds of holoenzyme assembly. Such a mechanism could overcome transient limitations on the availability of sigma 70 or core polymerase after a prolonged stationary phase.
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PMID:FIS and RNA polymerase holoenzyme form a specific nucleoprotein complex at a stable RNA promoter. 753 15

All transcription terminators for RNA polymerase I (pol I) that have been studied so far, ranging from yeast to humans, require a specific DNA binding protein to cause termination. In yeast, this terminator protein has been identified as Reb1p. We now show that, in addition to the binding site for Reb1p, the yeast pol I terminator also requires the presence of a T-rich region coding for the last 12 nucleotides of the transcript. Reb1p cooperates with this T-rich element, both to pause the polymerase and to effect release of the transcript. These findings have implications for the termination mechanism used by all three nuclear RNA polymerases, since all three are known to pause at this terminator.
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PMID:Transcription termination of RNA polymerase I due to a T-rich element interacting with Reb1p. 756 17

Termination of mouse ribosomal gene transcription by RNA polymerase I (Pol I) requires the specific interaction of a DNA binding protein, mTTF-I, with an 18 bp sequence element located downstream of the rRNA coding region. Here we describe the molecular cloning and functional characterization of the cDNA encoding this transcription termination factor. Recombinant mTTF-I binds specifically to the murine terminator elements and terminates Pol I transcription in a reconstituted in vitro system. Deletion analysis has defined a modular structure of mTTF-I comprising a dispensable N-terminal half, a large C-terminal DNA binding region and an internal domain which is required for transcription termination. Significantly, the C-terminal region of mTTF-I reveals striking homology to the DNA binding domains of the proto-oncogene c-Myb and the yeast transcription factor Reb1p. Site-directed mutagenesis of one of the tryptophan residues that is conserved in the homology region of c-Myb, Reb1p and mTTF-I abolishes specific DNA binding, a finding which underscores the functional relevance of these residues in DNA-protein interactions.
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PMID:Different domains of the murine RNA polymerase I-specific termination factor mTTF-I serve distinct functions in transcription termination. 772 Jul 15

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