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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)

A method was devised for directing RNA polymerase on a single promoter site on T7 DNA. Initiation complexes were formed on each of the three main promoter sites using one dinucleotide plus one nucleoside triphosphate. The ternary initiation complexes are resistant to rifampicin action, to inhibition by (rI)n at 0 degrees C and are stable at high salt concentrations. A minimum of a trinucleotide is required to form a stable ternary complex. To determine which promoter site was selected by RNA polymerase during initiation, the (rI)n-resistant RNA was digested by RNAse III to generate three characteristic initiator RNA fragments, resolved by gel electrophoresis. The three major promoter sites could be selected individually by using different primer and substrate combinations ApC plus ATP selected promoter A3, CpG plus CTP selected A2 and CpC plus ATP specified preferentially A1. A number of primer-substrate combinations specified each site at low salt concentration but the substrate requirement became very stringent at high salt concentration, suggesting that the postulated local opening of the promoter site could be more or less extensive, depending on the ionic strength. The minimum opening observed at high salt concentration corresponded to the insertion of a leader trinucleotide sequence. The promoter region melted by RNA polymerase at low salt concentration was (G plus C)-rich and corresponded to about 9 to 11 base pairs. Sequences of the melting recognition regions were tentatively inferred from the results.
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PMID:Interaction of RNA polymerase from Escherichia coli with DNA. Analysis of T7 DNA early-promoter sites. 110 Apr 9

Circular dichroic spectra of T7 RNA polymerase show minima at 222 nm ([theta]m=-7.9 X 10(3) deg cm2/dmol) and 208 nm ([theta]m =-7.55 X 10(3) deg cm2/dmol) and a maximum at 193 nm ([theta]m = 1.2 X 10(4) deg cm2/dmol). The small mean residue ellipticity above 200 nm indicates that the secondary structure contains approximately 12% alpha helix. The secondary structure is unaltered by high salt, glycerol, -SH reagents, nitration of tyrosyl residues, and chelating agents. Binding of the native enzyme to [32P]T7 DNA has been measured by the retention of the protein-[32P]DNA complexes on nitrocellulose filters. At 37degrees T7 RNA polymerase binds to its promoters in the absence of NTP's. Binding and catalytic activity are both abolished at 0degree. Binding of the initiating [gamma-32P]GTP can also be detected by the filter binding assay. Native T7 RNA polymerase is inactivated by reaction with 1 mol of 5,5'-dithiobis(2-nitrobenzoic acid) (Nbs2) or 1 mol of [14C]iodoacetamide. The latter reaction is blocked by Nbs2 suggesting that a single -SH group is required for activity. Alkylation of the -SH group does not alter binding of the enzyme to the DNA template, but modifies the binding of GTP to the enzyme. Nitration of approximately4 surface tyrosyl residues of the protein prevents binding to T7 DNA. The restriction endonuclease, Hpa II, cuts T7 DNA into approximately40 fragments and reduces total RNA synthesis by T7 RNA polymerase by 70%. Fragmentation of the DNA template by Hpa II does not alter the rate of RNA chain initiation by T7 polymerase, and restriction fragments accounting for approximately25% of the T7 DNA still bind tightly to the enzyme. Thus the T7 RNA polymerase promoters remain intact on the restriction fragments. Gel electrophoresis of the transcription products, using restriction fragments as templates, show that of the seven in vitro transcripts produced by T7 RNA polymerase from whole T7 DNA, only the smallest (representing the last 1.5% of the genome) is transcribed from Hpa II fragments. The remaining transcripts are replaced by six new and much shorter mRNA's. The DNA fragments containing the promoters for these mRNA's have been removed from the fragment mix by binding them to the enzyme and retaining the complexes on nitrocellulose filters.
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PMID:T7 RNA polymerase: conformation, functional groups, and promotor binding. 110 55

Studies of RNA chain initiation have suggested that the sigma subunit of Escherichia coli RNA polymerase (RNA nucleotidyltransferase; nucleosidetriphosphate: RNA nucleotidyltransferase; EC 2.7.7.6) is released from the enzyme-template complex during transcription and may be reused by another core polymerase. Nanosecond fluorescence depolarization spectroscopy was used to follow the sigma cycle. Isolated sigma subunit labeled with the fluorescent probe dansyl (DNS) chloride bound stoichiometrically to core polymerase and stimulated transcription of phage T7 DNA to the same extent as did unlabeled sigma. DNS-sigma showed an exponential fluorescence anisotropy decay corresponding to a rotational correlation time of about 100 nsec. This value was unaffected by addition of T7 DNA, but increased about 6-fold when core polymerase was added, and increased further when T7 DNA was added. Such increases are expected for the formation of molecular complexes. Using the anisotropy decays for free DNS-sigma and DNS-sigma-core enzyme bound to T7 DNA, we calculated theoretical decay curves for various mixtures of free and bound sigma. Comparison of the observed anisotropy decay with the calculated curves indicated that about 55% of DNA-sigma was released from the enzyme-T7 DNA complex in the presence of four nucleoside triphosphates under low salt conditions. Sigma release did not occur if rifampicin was added prior to addition of four nucleoside triphosphates or if only three nucleoside triphosphates were present. After sigma was released, addition of core polymerase with rifampicin reduced the free sigma to less than 15%, indicating that the released sigma was accessible to the added core enzyme. Thus these studies have provided physical evidence for the sigma cycle during in vitro transcription.
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PMID:Sigma cycle during in vitro transcription: demonstration by nanosecond fluorescence depolarization spectroscopy. 110 33

The nature of the inhibition by salt (KCl) of DNA-dependent RNA polymerase from T4 phage-infected Escherichia coli (T4 enzyme) was studied using holoenzyme preparations, core enzyme and sigma fractions obtained by phosphocellulose column chromatography, and sigma fractions further purified by gradient centrifugation in the presence and absence of 6 M urea. We showed with holoenzyme preparations that salt inhibits the formation of rifampicin-resistant preinitiation complexes. The inhibition was considerably reduced when a nonionic detergent (particularly of the Triton series) was included in the reaction mixtures. With T4 core enzyme and T4 sigma fractions together with the same fractions from uninfected cells (host enzyme fractions) and different DNA templates, we showed that the T4 sigma fraction plays a role in the salt-sensitive activity with T4 DNA. The salt sensitivity of the T4 sigma fraction was antagonized by Triton; it was not a function of sigma fractions isolated from phage cultures infected in the presence of chloramphenicol. As reported previously (Stevens, A. (1973), Biochem. Biophys. Res. Commun. 54, 488), the T4 sigma fraction inhibited the activity of host sigma when they were present together in reaction mixtures, particularly in the presence of salt. T4 sigma further purified by centrifugation in glycerol gradients had the same properties as the cruder fraction, and the T4-specific polypeptide of mol wt 10000 (Stevens, A. (1972), Proc. Natl. Acad. Sci. U.S.A. 69, 603) was found in the same fractions. If the glycerol gradients contained 6 M urea, the mol wt 10000 polypeptide was separated from the salt-stimulated sigma. Fractions containing the small polypeptide could be added back to produce the salt-inhibitory effects. The inhibitory activity of both the crude sigma fraction and the fractions containing the small polypeptide was inactivated at 65 degrees C. The results suggest that the mol wt 10000 protein is a salt-promoted inhibitor, but the small amounts of it which are present in purified fractions of the T4 enzyme have not yet allowed its isolation in large enough quantities to permit a detailed study of its properties.
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PMID:Characterization of an inhibitor causing potassium chloride sensitivity of an RNA polymerase from T4 phage-infected Escherichia coli. 110 66

1. RNA polymerase from Escherichia coli is selectively and strongly retained by a heparin-substituted agarose and can be eluted therefrom by a neutral buffer containing 0.6 M salt. The method is applicable to relatively crude preparations of the enzyme on a preparative scale giving highly purified RNA polymerase in excellent yield. The enzyme obtained by this procedure shows the highest specific activity so far reported and is pure and enriched in factor sigma as indicated by dodecylsulfate gel electrophoresis. 2. Based on the differential affinity of the subunits of the enzyme for the heparin-carrying gel matrix, a method for separation of alpha, beta' + beta and sigma subunits by application of urea and salt-containing buffers is described. Upon recombination and dialysis with urea-free buffer 40-50% of the enzyme activity is restored.
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PMID:Rapid isolation of highly active RNA polymerase from Escherichia coli and its subunits by matrix-bound heparin. 110 37

When chromatin prepared from WI-L2 lymphocytes by low salt extraction and shearing is centrifuged on a glycerol gradient, one area of the gradient yields chromatin enriched in template activity for Escherichia coli DNA-dependent RNA polymerase (EC 2.7.7.6; nucleosidetriphosphate:RNA nucleotidyltransferase) as compared to Saccharomyces cerevisiae RNA polymerase II (or B). Another area yields chromatin preferred by the eukaryotic enzyme. Kinetic studies indicate that the differences in activity cannot be explained by differences in affinity of the enzymes for the various templates. The DNA isolated from either fraction has a molecular weight of 8.5 X 106. The "yeast active" fraction seems enriched in proteins. Mixing experiments indicate that the yeast enzyme does not alter the template in such a way as to improve it for the bacterial enzyme.
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PMID:Separation of lymphocyte chromatin into template-active fractions with specificity for eukaryotic RNA polymerase II or prokaryotic RNA polymerase. 110 5

Formation of complexes between f2 RNA polymerase cistron was partially inhibited, some RNA and coat protein was studied using salt conditions which are optimum for phage protein synthesis. In this ionic environment, coat protein precipitation can be prevented by sulfhydryl group-protecting agents. Complexes formed at different protein-RNA input molar ratios were isolated and tested for template activity in an in vitro protein synthesizing system. Simultaneously, the number of protein molecules bound per RNA strand in such complexes was measured by the membrane (Millipore) filtration technique. Under conditions in which translation of the RNA strands were complexed with six molecules of coat protein, whereas some remained unbound. Strong inhibition of the translation of the RNA polymerase cistron was observed when each of the RNA strands present in the mixture was associated with six molecules of coat protein.
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PMID:Template activity of complexes formed between bacteriophage f2 RNA and coat protein. 111 77

A procedure has been developed for the purification of soluble DNA-dependent RNA polymerase (EC 2.7.7.6) from rye embryos. The enzyme solubilized by high salt extraction with sonication and resolved by DEAE-cellulose chromatography yields two activities. Enzyme I eluted at 0.15 M (NN4)2SO4, was insensitive to alpha-amanitin and was extremely labile. Enzyme II eluted at 0.25 M (NH4)2SO4 was inhibited by alpha-amanitin. However, DEAE-Sephadex chromatography yields three DNA-dependent RNA polymerases. Enzyme I is resistant to amanitin, while II and III enzymes are inhibited by this poison. Partially purified on DEAE-cellulose, polymerase II was further purified by hydrophobic chromatography on an omega-aminobutyl-Sepharose column. After omega-aminobutyl-Sepharose chromatography, enzyme II was stable and was more active with denatured than with native DNA as template. The activity of purified RNA polymerase II is dependent on the DNA, Mn-2+ and Mg-2+ added and requires ATP, GTP, CTP and UTP for its maximum activity. Transcription is inhibited besides by alpha-amanitin, by chromomycin A3, daunomycin, ethidium bromide and actinomycin D. Rifampin and rifamycin SV do not inhibit the enzyme. Synthetic copolymers were also effective as templates.
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PMID:Isolation and purification of RNA polymerases from rye embryos. 112 11

Bovine lymphosarcoma tissue has been extracted with low- and high-salt buffers [0.05 M Tris-C1 plus or minus 0.3 M (NH4) 2S04]. Diethylaminoethyl-Sephadex chromatography of both the high-salt and low-salt extracts yields RNA polymerases I and II, although low-salt extraction releases only one-third as much activity. Extraction by high salt of the residue from the low-salt extract, followed by diethylaminoethyl-Sephadex chromatography, yields additional enzyme activity with properties of Form II. Purification of the low-salt extract by protamine precipitation, elution with sodium succinate, and phosphocellulose chromatography yields a preparation of RNA polymerase (RNAP) with hybrid properties, combining the salt optimum of Form I, diethylaminoethyl-Sephadex elution pattern of form II, and alpha-amanitin sensitivity of Form III. RNAP. transcribes native D,A and chromatin efficiently. More RNAPL is recovered from lymphosarcoma tissue than from calf thymus.
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PMID:RNA polymerase isolated from bovine lymphosarcoma by sequential low- and high-salt extraction. 117 19

Poly(A) polymerase has been extensively purified from low-salt extracts of bovine lymphosarcoma. The enzyme is Mn2+ dependent, requires an oligonucleotide or RNA primer, incorporates only adenosine triphosphate, and is inhibited by other ribonucleotides or deoxynucleotides. Oligoadenylate and ribosomal RNA are good primers for the enzyme; transfer RNA and poly(A) are poor. RNA transcribed in vitro by homologous RNA polymerase is an efficient primer. The properties of the enzyme are similar to the properties of the Mn2+ -activated poly(A) polymerase of calf thymus. Approximately the same amount of enzyme appears to be present in lymphosarcoma and calf thymus.
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PMID:Poly (A) polymerase of bovine lymphosarcoma. 117 55

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