Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Replicative form DNA of bacteriophage fd, which had been fragmented with the restriction endonuclease II from Hemophilus parainfluenzae (endo R- HpaII), was reacted with Escherichia coli RNA polymerase; the resulting stable preinitiation complexes were analysed using the filter binding assay followed by gel electrophoresis. At 120mM KCL the first-order rate constants for complex decay were determined to be 10(-2)-10(-6)s-1. The second-order rate constants for complex formation were found to be about 10(6) -10(7) M-1 s-1. From these values association constants for the individual promoters were calculated to be 2 x 10(-8) -2 x 10(-11) M-1. The rate of formation and the stability of promoter complexes was enhanced in superhelical DNA. No evidence was found for stable promoter-specific closed complexes consisting of enzyme and helical DNA. This and the kinetic data suggest that the unwinding of base pairs is already important early in promoter selection, and not only for the formation of the final open complex. The initiation of RNA synthesis form the preinitiation complex was faster than complex dissociation and complex formation for all promoters. Consequently, the initiation efficiency of a promoter is determined by the rate of complex formation, and not by its 'affinity' for the enzyme. No correlation was found between the relative order of the fd promoters for the binding and the dissociation reaction. This is explained by different structural determinants, for the two reactions, which are located in different parts of the promoter DNA.
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PMID:Interaction of RNA polymerase with promoters from bacteriophage fd. 30 Jun 80

Both forms A and B RNA polymerases solubilised from rat liver nuclei transcribed templates within these organelles when added exogenously to freshly prepared nuclei. The enzymes initiated more efficiently in the presence of KCL than ammonium sulphate and required manganese rather than magnesium as the divalent cation. Form A enzyme initiated most successfully at 375 mM KC6, activity was proportional to the amount of template added and continued linearly for at least 30 min. Form B enzyme initiated with two ionic strength optima, 125 mM and 500 mM KCl. Activity in the latter case was critically dependent on the enzyme: nuclei ratio. In both instances incorporation of nucleotide precurors was linear for less than 20 min. Form A enzyme synthesised products with a size distribution mainly larger than 18 S; form B enzyme synthesised products of mainly less than 5 S at 125 mM KCl and about 10 S at 500 mM KCl. Subfractionation of nuclei indicated that exogenous RNA polymerase A activity and form B at 125 mM KCl were occurring in nucleoli; form B activity at 500 mM KCl was nucleoplasmic. Measurements of U : G ratios in the RNA products suggested that exogenous form A was synthesising species with similar base ratios to the ribosomal RNA precurosrs. Both enzymes formed rifamycin AF/0-13 resistant complexes with nucleolar templates. Size analyses of products showed that whereas form B enzyme synthesised very small RNA species, RNA polymerase A produced a range of species of similar sizes to the ribosomal RNA precurosors.
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PMID:Transcription of isolated nuclei and nucleoli by exogenous RNA polymerase A and B. 114 40