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 L and NS proteins of vesicular stomatitis virions (New Jersey serotype) were solubilized with Triton X-100 and high-salt buffer and recombined with purified nucleocapsids under conditions similar to those used to reconstitute transcriptase activity in vitro. The nucleocapsid-bound L and NS proteins were separated from unbound proteins on a glycerol gradient. The rebinding of L and NS proteins mimics the in vivo binding in that at saturation the ratio of L and NS molecules to N molecules is approximately the same as observed in the intact virion. L and NS proteins were separated and added back independently and in combination to the template. The purified NS protein bound to the template in the absence of L protein. However, the L protein binding appeared to depend on the presence of NS protein. The presence of Mg2+ and nucleotides, which is required for transcription, was not necessary for the rebinding of L and NS proteins.
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PMID:Rebinding of transcriptase components (L and NS proteins) to the nucleocapsid template of vesicular stomatitis virus. 21 81

The more than 2,300-fold purification of a DNA polymerase from the embryos of Drosophila melanogaster is described. The enzyme, which forms a single band on gel electrophoresis, has a molecular weight of about 87,000 and a pH optimum of 8.5. A divalent metal is required for activity, Mg2+ being preferred with activated DNA, Mn2+ with homopolymer template-primers. The enzyme is inactivated completely by mercurials; polyamines are also inhibitory with certain templates. The most efficient template-primer is activated DNA, but homopolymers such as poly(dA)-oligo(dT), poly(A)-oligo(dT), and poly(A)-oligo(U) are also utilized with high efficiency. The purified enzyme preparations appear to be devoid of nuclease activity when assayed directly with suitable substrates. In addition, neither primer nor product is degraded after prolonged incubation with the enzyme. In accordance with previous observations on other DNA polymerases, the Drosophila enzyme can replicate single-stranded DNA only under conditions of simultaneous transcription by RNA polymerase.
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PMID:A DNA polymerase from embryos of Drosophila melanogaster. Purification and properties. 24 52

Purified yeast DNA was transcribed by homologous RNA polymerases I and II and Escherichia coli RNA polymerase. Transcripts synthesized in vitro were analyzed by molecular hybridization with complementary DNA (cDNA) synthesized from yeast poly(A)-containing mRNA with viral reverse transcriptase and ribosomal DNA labeled in vitro by nick translation with E. coli DNA polymerase I. RNA synthesized by polymerase I and II in the presence of Mn2+ contained sequences complementary to cDNA and rDNA at a frequency consistent with random transcription of the template. Similarly, E. coli RNA polymerase synthesized an apparently random transcript in the presence of either Mn2+ or Mg2+. In contrast to these results, RNA polymerase I but not polymerase II transcripts were markedly enriched in sequences complementary to rDNA when transcription was carried out in the presence of Mg2+. The observed enrichment was 15-30-fold higher than observed for polymerase II or E. coli polymerase transcripts and is consistent with the transcript being comprised of 6-10% ribosomal sequences. These data strongly suggest that RNA polymerase I plays a critical role in selective transcription of ribosomal cistrons.
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PMID:Transcription of yeast DNA by homologous RNA polymerases I and II: selective transcription of ribosomal genes by RNA polymerase I. 31 52

We investigated the ribonucleolytic breakdown of poly(U), poly(A), RNA trascribed from calf thymus DNA with E. coli RNA polymerase, ribosomal RNA, tRNA and mengovirus RNA by an enzyme fraction obrained from a postribosomal supernatant of Ehrlich ascites tumor cells. The single-stranded homopolyribonucleotides are preferentially degraded by the enzyme fraction with the production of ribonucleoside 5'-monophosphates. The RNase activity is completely dependent on the presence of Mg2+ ions and is highest at Mg2+ and K+ concentrations optimal for cell-free protein synthesis. Ribonucleoside 5'-monophosphates, ribonucleoside 2'(3')-monophosphates, ribonucleoside 2'(3'),5'-bisphosphates and transition state analogs consisting of vanadyl sulfate and either ribonucleosides or ribonucleoside 5'-monophosphates in a molar ratio 1:1 inhibit the ribonucleolytic activity of the enzyme fraction. The ribonucleoside 2'(3'),5'-bisphosphates and the transition state analogs are the most effective inhibitors. However, only in the presence of ribonucleoside 2'(3'),5'-bisphosphates a concomitant stimulation by 50 to 60% of poly(U)-directed polyphenylalanine synthesis is observed; all the other RNase inhibitors tested also inhibit polypeptide synthesis. The results of preliminary experiments show that poly(U) and ribonucleoside 2'(3'),5'-bisphosphates are well suited as ligands for affinity chromatography of ribonucleases from Ehrlich ascites tumor cells.
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PMID:Inhibition of ribonucleases by ribonucleotides and transition state analogs in cell-free extracts from Ehrlich ascites tumor cells. 32 84

Conversion of the viral DNA of phage G4 to the duplex form provided an opportunity to isolate and determine the function of the dnaG protein, the product of a gene known to be essential for replication of the Escherichia coli chromosome. This stage of G4 DNA replication requires action of three proteins: the E. coli DNA-binding protein, the dnaG protein, and the DNA polymerase III holoenzyme. The dnaG protein has been purified approximately 25,000-fold to near-homogeneity. The native protein contains a single polypeptide of 60,000 daltons. It has been assayed for its activity on G4 DNA in three ways: (a) RNA synthesis, (b) complementation for replication of an extract of a temperature-sensitive dnaG mutant, and (c) priming of DNA replication by DNA polymerase III holoenzyme. The dnaG protein is highly specific for G4 DNA and synthesizes a unique 29-residue RNA primer to be described in the suceeding paper. Other single-stranded and duplex DNA templates are inactive. RNA primer synthesis by the dnaG protein has an apparent Km for ribonucleoside triphosphates near 10 micrometer, and a narrow optimum for Mg2+. The sharp specificity of the dnaG protein in choice of template and the utilization of either deoxyribonucleotides or ribonucleotides to produce a hybrid piece only a few residues long (as described in a succeeding paper) suggests that the dnaG protein previously named RNA polymerase by renamed primase.
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PMID:Primase, the dnaG protein of Escherichia coli. An enzyme which starts DNA chains. 34 Apr 57

Adenosine 2',3'-riboepoxide 5'-triphosphate (epoxyATP) has been found to be a suicidal inactivator of DNA polymerase I from Escherichia coli by the following criteria. Inactivation is complete, is first order in enzyme activity, and shows saturation kinetics with an apparent KD of 30 +/- 10 micron for epoxy ATP. This KD is comparable to the KM of the substrate dATP. The t1/2 for inactivation is 1.3 min. Inactivation requires Mg2+ and the complementary template. The enzyme is protected by dATP but not by an excess of template. Gel filtration of the reaction mixture after inactivation with [3H]epoxy ATP results in the comigration of E. coli DNA polymerase I, the tritium-labeled inactivator, and the DNA template. The stoichiometry of binding approaches 1 mol of [3H]epoxy nucleotide per mol of inactivated enzyme. These results are consistent with the hypothesis that epoxy ATP initially serves as a substrate for the polymerase reaction, elongating the DNA chain by a nucleotidyl unit, and subsequently alkylates an essential base at the primer terminus binding site of the enzyme. Epoxy ATP also inactivates human and viral DNA polymerases but not E. coli RNA polymerase or rabbit muscle pyruvate kinase. Hence epoxy ATP may be a specific suicide reagent for DNA polymerases.
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PMID:Apparent suicidal inactivation of DNA polymerase by adenosine 2',3'-riboepoxide 5'-triphosphate. 34 91

We have investigated the nonspecific interactions of Escherichia coli RNA polymerase core and holoenzyme with double-stranded (ds) and single-stranded (ss) DNA. Binding constants for these interactions as functions of such solution variables as monovalent and/or divalent cation concentration, temperature, or pH were determined by the method of deHaseth et a. [deHaseth, P.L., Gross, C.A., Burgess, R.R. and Record, M.T. (1977), Biochemistry 16, 4777--4783] from analysis of the elution of the proteins from small columns containing immobilized DNA. This technique, although as yet empirical, has been demonstrated to yield accurate binding constants fot the nonspecific interation of lac repressor with ds DNA. We find that observed binding constants (Kobsd) are extraordinarily sensitive functions of the monovalent cation concentration for the interactions of both core and holoenzyme with ds DNA. In the absence of divalent cations, the derivatives --(d log Kobsd/d log [Na+]) are 11 +/- 2 for the holo--ds DNA interaction and 21 +/- 3 for the core--ds DNA interaction. Consequently, approximately 11 and 21 low-molecular-weight ions are released, iin the thermodynamic sense, in the formation of the holo--ds and core--ds complexes, respectively (Record, M.T., Jr., Lohman, T.M., and deHaseth, P.L. (1976), J. Mol. Biol. 107, 145--158; Record, M.T., Jr., Anderson, C.F., and Lohman, T.M. (1978), Q. Rev. Biophys., in press). Ion release is a thermodynamic driving force for these nonspecific interactions and causes the stability of the complexes to increase very substantially with a reduction in monovalent ion concnetration. Possible molecular models which account for the different salt sensitivities of the holo--ds and core--ds complexes are discussed. Effects of the competitive ligand Mg2+ on these interactions are also examined. Substantial ion release (approximately 18 monovalent ions) also accompanies the interaction of either holo or core polymerase with ss DNA. Over the range of ion concentrations investigated the holo--ss interaction is substantially stronger than the core--ss interaction; furthermore, we conclude that the interactions of polymerase with ss DNA are, in general, stronger than the nonspecific interations of the enzyme with ds DNA. It is likely that the nonspecific interactions of RNA polymerase with DNA have physiological relevance. Not only is it plausible to assume that the same regions of the protein are involved in both specific and nonspecific interactions, but in addition nonspecific interactions of RNA polymerase and DNA may play role in determining the availability of this protein, in both the thermodynamic and the kinetic sense, for promoter binding and RNA chain initiation [von Hippel. P.H., Revzin, A., Gross, C.A., and Wang, A.C. (1974), Proc. Natl. Acad. Sci U.S.A. 71, 4808--4812]. Consequently, the strong dependences of the nonspecific interactions of RNA polymerase on ionic conditions suggest the possibility of a modulating role of ion concentrations in the control of transcription.
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PMID:Nonspecific interactions of Escherichia coli RNA polymerase with native and denatured DNA: differences in the binding behavior of core and holoenzyme. 35 Feb 71

In the presence of Mn2+, globin mRNA can be transcribed into a partial RNA copy by Escherichia coli RNA polymerase. This process also occurs when the mRNA is transcribed together with chromatin. A fraction, at least, of the newly synthesized RNA copy (anti-globin RNA) can serve as a template for the synthesis of globin sequences of the same polarity as the original mRNA. This process is sufficient to explain the specific synthesis of a subset of the globin RNA on mouse foetal liver chromatin. It also accounts for the synthesis of double-stranded RNA sequence by E. coli RNA polymerase, on chromatin as well as on pure mRNA. Results are presented suggesting that the poly(A) tract of the mRNA could be preferentially transcribed. In the presence of Mg2+, the RNA-dependent transcription is strongly inhibited, as well as the synthesis of double-stranded RNA. Under these conditions, the transcription on chromatin appears to be largely DNA dependent, and the synthesis of globin sequences is completely asymmetric. Spermine (0.3 mM) seems to improve the specificity of transcription. The transcription of chromatin in vitro is thus largely dependent on the nature of the divalent cation present in the in the incubation mixture.
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PMID:Specificity of chromatin transcription in vitro. Anomalies due to RNA-dependent RNA synthesis. 37 4

The interaction of granaticin B, a quinone antibiotic produced by Streptomyces granaticolor, with some biologically important bivalent metal ions, DNA and ATP was demonstrated spectrophotometrically. The activity of isolated RNA polymerase was higher when the DNA of phage SP 50 served as template than with DNA isolated from Bacillus subtilis. Granaticin B inhibited in vitro RNA synthesis, similarly to certain other antibiotics (the inhibition was three times lower than that caused by actinomycin D or streptolydigin and slightly higher than that by epsilon-pyrromycinone). The inhibitory effect was higher when the Mg2+ concentration in the reaction mixture was decreased. The inhibition was then proportional to the concentration of the DNA template. DNA-dependent RNA synthesis is thus inhibited in vitro by granaticin B but this does not appear to be the only site of action of this antibiotic in vivo.
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PMID:Interaction of granaticin B with the transcription system of Bacillus subtilis. 41 19

Analogously as in the 32-cell stage [20], in the 4-, and 8-cell generations of antheridial filaments of Chara vulgaris, the activity of DNA dependent RNA polymerase detected in situ as well as the 3H uridine incorporation increase in the middle S phase and in the middle G2 phase, while they decrease considerably at the end of S phase and in late G2 phase. The diphasic changes occur both in the nucleolar and extranucleolar (nucleoplasmic) activity of RNA polymerase as well as in the 3H uridine incorporation. However, the maximum nucleolar activity, in both S and G2 phases, precedes the peak of nucleoplasmic activity. During the increased nucleolar activity RNA polymerase (as calculated per nucleus) shows a higher level as compared with nucleoplasmic RNA polymerase, whereas the intensity of 3H uridine incorporation into nucleous and nucleoplasm is similar. It may be supposed that the incubation environment containing Mg2+ used in vitro is more stimulating for the nucleolar RNA polymerase than for the nucleoplasmic RNA polymerase. The mean transcriptional activity of the nucleus and the activity of RNA polymerase in the 8-cell generation is about 20% lower than in the 4-cell generation, in proportion to the decrease in cell sizes.
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PMID:Changes in the activity of RNA polymerase detected in situ and the intensity of 3H uridine incorporation into the nucleolus and the nucleus of interphase cells in antheridial filaments of Chara vulgaris L. 48 62

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