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 subunit structure of Caulobacter crescentus chromatin has been proven by electron microscope studies. The use of EDTA-Na2 during the purification of the chromatin complex enhanced the removal of contaminating ribosomes and non-chromatin proteins. The preparation obtained by modified procedure contained RNA polymerase as one of the major proteins and three histone-like proteins (10 K, 17 K and a hitherto not described protein with mol. wt 14 K).
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PMID:Isolation and characterization of chromatin from Caulobacter crescentus. 241 9

To elucidate the mechanism of sigma release in the transcript by Escherichia coli DNA-dependent RNA polymerase, we obtained the time courses of sigma release and elongation of product RNA by a rapid kinetic technique; transcription was synchronously initiated from A1 promoter on T7 DNA by the addition of four substrates to a stoichiometric mixture of holoenzyme and template DNA, and then quenched by the addition of EDTA. The elongation rate was changed by limiting the concentration of one of four substrates, GTP. At reduced GTP concentration, elongation was decelerated, but the time course of sigma release was unchanged. No connection between sigma release and length of RNA product was found. The results lead to the conclusion that sigma is released depending only on time elapsed after initiation, not on the length of RNA product. We propose a two-step model for sigma release with a rapid triggering and a slow dissociation of about 5 s. This dissociation, the rate-determining step of sigma release, is independent of the rate of elongation.
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PMID:Release of the sigma subunit of Escherichia coli DNA-dependent RNA polymerase depends mainly on time elapsed after the start of initiation, not on length of product RNA. 242 13

The interactions of T7 RNA polymerase with its promoter DNA have been previously probed in footprinting experiments with either DNase I or (methidiumpropyl-EDTA)-Fe(II) to cleave unprotected DNA [Basu, S., & Maitra, U. (1986) J. Mol. Biol. 190, 425-437. Ikeda, R. A., & Richardson, C. C. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 3614-3618]. Both of these reagents have drawbacks; DNase I is a bulky reagent and so provides low resolution, and (methidiumpropyl-EDTA)-Fe(II) intercalates into DNA and is therefore biased toward cleavage of double-stranded DNA. In this study, the interaction between the polymerase and the promoter has been probed with Fe(II)-EDTA. This reagent generates reactive hydroxyl radicals free in solution, which produces a more detailed picture of the polymerase-promoter complex. Two protected regions are observed on each of the two promoter DNA strands: from position -17 to position -13 and from position -7 to position -1 on the coding strand and from position -14 to position -9 and from position -3 to position +2 on the noncoding strand. From this pattern it is clear that if recognition occurs via double-stranded B-form DNA, then the protected regions lie on one face of the DNA helix, and therefore the enzyme must interact predominantly from one side of the DNA helix. Digestion of the DNA in a polymerase-promoter complex with a single-strand-specific endonuclease shows that a small region of the noncoding strand near position -5 is susceptible to cleavage.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:T7 RNA polymerase interacts with its promoter from one side of the DNA helix. 254 54

The interactions of T7 RNA polymerase with T7 late promoters were studied by using quantitative footprinting with methidiumpropyl-EDTA X Fe(II) [MPE-Fe(II)] as the DNA cleaving agent. Class II and class III T7 promoters have a highly conserved 23 base pair sequence from -17 to +6. Among class III promoters the -22 to -18 region is also highly conserved. For a class II promoter, T7 RNA polymerase protects the -17 to -4 region from MPE-Fe(II) cleavage; when GTP is present, protection extends from -17 to +5 (noncoding strand). For a class III promoter, protection extends from -20 to -4 and in the presence of GTP from -20 to +5 (noncoding strand). The protected regions for the coding strands of both promoters were nearly identical with that seen for the noncoding strands. The binding constant for the class III promoter is (4 +/- 1.5) X 10(7) M-1 and in the presence of GTP increases to (10 +/- 1.7) X 10(7) M-1. These binding constants are about 1000 and 200 times greater, respectively, than values reported previously [Ikeda, R. A., & Richardson, C. C. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 3614-3618]. The differences in binding constants are probably due to tRNA and high salt used in those earlier experiments. Both tRNA and high salt (greater than 50 mM NaCl and greater than 10 mM MgCl2) inhibit the binding of the polymerase to the promoter. Optimal binding conditions occur at 2-5 mM MgCl2 and 0-10 mM NaCl.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Interactions of T7 RNA polymerase with T7 late promoters measured by footprinting with methidiumpropyl-EDTA-iron(II). 303 3

Yeast mitochondrial RNA polymerase can bind specifically to promoter-containing DNA fragments in vitro as detected by DNAse I or methidiumpropyl-EDTA. Fe(II) protection assays and gel retardation experiments. Retardation of RNA polymerase-DNA complexes was most pronounced when the promoter was located in the middle of a DNA fragment and was diminished when RNA polymerase was bound near one of the ends. This indicates that upon RNA polymerase-binding the DNA undergoes a conformational change which is most likely a bend. The degree of introduced bending correlated with the efficiency of transcription and promoter-binding in a series of promoter mutants, suggesting that bending is a functional event during promoter utilisation.
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PMID:RNA polymerase induces DNA bending at yeast mitochondrial promoters. 305 Aug 96

Three subspecies of RNA polymerase II, designated IIO, IIA, and IIB, have been described in a variety of eukaryotic cells and shown to differ in the molecular weight of their largest subunit, designated IIo, IIa, and IIb, respectively. The objectives of this study were to establish the in vivo molecular structure of RNA polymerase II in mammalian cells and to examine conditions that influence the stability of RNA polymerase II subspecies. Subunit affinity-purified antibodies were used to determine the relative concentration of subunits IIo, IIa, and IIb in crude extracts of calf thymus tissue, cultured bovine kidney cells, and HeLa cells. HeLa cells contain exclusively RNA polymerase IIO whereas both cultured bovine kidney cells and calf thymus tissue contain RNA polymerases IIO and IIA. RNA polymerase IIB was not detected at significant levels in any of the cell extracts examined. Cell extracts were aged at either 4 degrees or 37 degrees C and the stability of RNA polymerases IIO and IIA determined by protein blotting. In the presence of buffer normally used for RNA polymerase purification, subunit IIo disappears from calf thymus extracts within 24 h at 4 degrees C or within 5 min at 37 degrees C. RNA polymerase IIO is partially stabilized by the inclusion of protease inhibitors and further stabilized by the presence of relatively high concentration of EDTA and EGTA. The prior fractionation of nuclei does not have an appreciable effect on RNA polymerase II stability. An increase in the amount of reducing agent causes a dramatic reduction in the stability of subunit IIo. The following manuscript (Bartholomew, B., Dahmus, M. E., and Meares, C. F. (1986) J. Biol. Chem. 14226-14231) examines the transcriptional activity of RNA polymerases IIO and IIA in reactions dependent on the major late promoter of adenovirus-2. Photoaffinity labeling of subunits IIo and IIa, relative to their concentration in the transcription extract, indicates that the transcriptional activity of RNA polymerase IIO is greater than 10 times that of IIA.
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PMID:Immunochemical analysis of mammalian RNA polymerase II subspecies. Stability and relative in vivo concentration. 309 16

RNA polymerase I binding to the eukaryotic ribosomal RNA gene promoter-transcription initiation factor (TIF) complex was examined by in vitro transcription and footprinting of a series of spacer mutants. Polymerase binds efficiently to the TIF-promoter complex independently of the DNA sequence in the polymerase interaction region and initiates transcription a fixed distance downstream of the TIF binding site on AT-rich templates. Methidiumpropyl-EDTA.FE(II) footprinting confirms minimal contacts between polymerase and DNA. We infer that polymerase is directed to the promoter by a DNA sequence-independent mechanism, solely by protein-protein contacts with TIF. An initiation step subsequent to binding requires special sequence characteristics in the transcription start site region.
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PMID:Eukaryotic RNA polymerase I promoter binding is directed by protein contacts with transcription initiation factor and is DNA sequence-independent. 311 36

By differential sucrose gradient centrifugation of pig kidney chromatin in the presence or absence of Na-EDTA and under varying ionic strength conditions, three nucleosome-like subpopulations with different buoyant densities can be obtained. These particles, on the basis of their histones and HMG protein pattern, of the 5-methylcytosine level of their DNA and of the RNA polymerase activity associated with them, can be considered as originating from chromatin fractions differently involved in gene expression. Two-dimensional electrophoresis of the tightly-bound non-histone proteins shows a distinct pattern for each subpopulation, such protein components being notably present in restricted numbers but in high amounts in the subpopulation which was apparently derived from condensed heterochromatin.
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PMID:Tightly-bound non-histone proteins in different nucleosome-like subpopulations from pig kidney chromatin. 334 69

Promoters for T7 RNA polymerase have a highly conserved sequence of 23 continuous base pairs located at position -17 to +6 relative to the initiation site for the RNA. The complex of T7 RNA polymerase with the phage phi 10 promoter has been visualized indirectly by exploiting the ability of the polymerase to protect DNA sequences from cleavage by methidiumpropyl-EDTA X Fe(II). The DNA contacts made by T7 RNA polymerase have been mapped during binding and during the subsequent initiation of transcription. The RNA polymerase alone protects 19 bases in a region from -21 to -3. Synthesis of the trinucleotide r(GGG) expands the length of the sequence protected by the RNA polymerase and stabilizes the complex; 29 bases (-21 to +8) are protected, and the observed equilibrium association constant of the r(GGG) complex is 5 X 10(5) M-1. The formation of a hexanucleotide mRNA, r(GGGAGA), further extends the protected region; 32 bases (-21 to +11) are protected. Finally, the synthesis of a pentadecanucleotide mRNA leads to a translocation of the region protected by the protein; the sequence now protected is reduced to 24 bases (-4 to +20).
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PMID:Interactions of the RNA polymerase of bacteriophage T7 with its promoter during binding and initiation of transcription. 345 46

RNA polymerase (RPase) from E. coli contains two tightly incorporated Zn(II) ions, while the monomeric RPase from bacteriophage T7 does not contain zinc and does not require Zn(II) in the assay. One of the two Zn(II) ions can be differentially removed from E. coli RPase with p-hydroxymercuriphenylsulfonate (PMPS) combined with EDTA and thiol. The resultant Znl or ZnA RPase shows no alteration in transcription initiation and elongation rate from sigma-specific promoters. Biosynthesis of a Co2 RPase and formation of CoA RPase by similar treatment shows the tetrahedral-type Co(II) d-d absorption bands to be associated only with the Co(II) at the A site with maxima at 760 (epsilon = 800), 710 (epsilon = 900), 602 (epsilon = 1500), and 484 (epsilon = 4000) nm. Sulfur to Co(II) charge transfer bands are present at 350 (epsilon = 9600) and 370 (epsilon = 9500) nm. The absorption characteristics strongly suggest that the A site is a tetrathiolate site. While DNA polymerases do not in general appear to contain zinc, gene 32 protein (g32P) from bacteriophage T4, an accessory protein essential for DNA replication and recombination and translational control in the T4 life cycle, is a Zn(II) metalloprotein and contains 1 gram atom of tightly incorporated Zn(II). PMPS displaces the zinc by reacting with three SH groups. Apo-g32P shows markedly altered DNA binding properties. Co(II) substitution gives a protein with intense d-d transitions typical of a tetrahedral Co(II) complex with absorption maxima at 680 (epsilon = 480), 645 (epsilon = 660), 605 (epsilon = 430), 355 (epsilon = 2250), and 320 (epsilon = 3175) nm. The data support a 3 Cys, 1 His coordination site located in the middle of the DNA binding domain of g32P. Data thus far suggest that the Zn(II) binding sites in multisubunit RNA polymerases and in accessory proteins involved in polynucleotide biosynthesis are more likely to play structural or allosteric (regulatory) roles rather than directly participating in catalysis.
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PMID:Zinc metalloproteins involved in replication and transcription. 354 19

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