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)

Bacteriophage T3-induced RNA polymerase is rapidly inactivated at 42 degrees C. Addition of T3 DNA delays this process for 30 s and reduces the rate with which the enzyme activity is lost indicating that a labile binary complex between T3 DNA and polymerase must have been formed. The ternary complex between T3-specific RNA polymerase, T3 DNA, and nascent RNA chains obtained when the enzyme is incubated with T3 DNA, GTP, ATP, and UTP is stable to heat (42 degrees C) and only slowly inactivated by polyvinyl sulfate. The optimal temperature for the formation of polyanionresistant ternary complexes is 30 degrees C while the elongation of T3 RNA chains proceeds fastest at 38 degrees C.
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PMID:Effect of temperature on the transcription by bacteriophage T3-induced RNA polymerase. 54 12

Class II DNA-dependent RNA polymerases were purified from soybean tissues of different physiological states: (1) from seed embryo tissue, representative of a quiescent, low metabolic state and (2) from auxin-treated hypocotyl tissue, representative of a highly proliferative and metabolically active state. Dodecyl sulfate, polyacrylamide gel electrophoresis indicates that RNA polymerase II from embryonic tissue consists largely (90-95%) of the form IIA enzyme, the largest subunit having a molecular weight of 215 000. RNA polymerase II from hypocotyl tissue is exclusively a form IIB enzyme, the largest subunit having a molecular weight of 180 000. Polypeptides common to RNA polymerases IIA and IIB have the following molecular weights: 138 000; 42 000; 27 000; 22 000; 19 000; 17 600; 17 000; 16 200; 16 100; and 14 000. Peptide mapping in the presence of dodecyl sulfate suggests that the 215 000 and 180 000 subunits possess similar peptide fragments. Plant embryo tissues do not contain protease activity capable of cleaving the 215 000 subunit to the 180 000 subunit, but proliferating plant tissues do contain such an activity. Mixing experiments indicate that appreciable amounts of RNA polymerase IIB are not being artifactually produced during protein purification.
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PMID:Plant DNA-dependent RNA polymerases: subunit structures and enzymatic properties of the class II enzymes from quiescent and proliferating tissues. 56 12

The DNA-dependent RNA polymerases II or B (ribonucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) from the mushroom Agaricus bisporus has been purified to apparent homogeneity. The purification procedures involve precipitation with polyethylenimine, selective elution of RNA polymerase II from the polyethylenimine precipitate, ammonium sulfate fractionation, DEAE-cellulose chromatography, CM-cellulose chromatography, and exclusion chromatography on Bio-Gel A-1.5M. With this procedure 11 mg of RNA polymerase II is recovered from 1.5 kg of mushroom tissue. RNA polymerase II from Agaricus bisporus has 12 subunits with the following molecular weights: 182,000, 140,000, 89,000, 69,000, 53,000, 41,000, 37,000, 31,000, 29,000, 25,000, 19,000, and 16,500. Purified RNA polymerase II from Agaricus bisporous was half-maximally inhibited by the mushroom toxin alpha-amanitin at a concentration of 6.5 microgram/mL (7 X 10(-6) M), which is 650-fold more resistant than mammalian RNA polymerases II. The apparent Ki for the alpha-amanitin-RNA polymerase complex was estimated to be 12 X 10(-6) M. The activity of purified RNA polymerase II from the mushroom was quite typical of other eukaryotic RNA polymerase II with regard to template preference, salt optima, and divalent metal cation optima.
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PMID:Purification and characterization of RNA polymerase II resistant to alpha-amanitin from the mushroom Agaricus bisporus. 57 Apr 13

DNA-dependent RNA polymerase from Micrococcus luteus can be isolated from cell extracts after removal of an excess of nucleic acids by fractionation with ammonium sulfate, followed by two consecutive gel filtrations through agarose and chromatography on cellulose phospate. Either homogeneous holoenzyme or a mixture of core and holoenzyme is obtained in this way, as is indicated by electrophoresis in polyacrylamide gels in the absence of detergent, where core enzyme migrates ahead of holoenzyme. Homogeneous core enzyme can be isolated from holoenzyme by chromatography on DEAE-cellulose. Core enzyme contains the subunits alpha, beta and beta' previously described [U.I. Lill et al., (1975) Eur. J. Biochem. 52, 411-420] in a molar ratio of 2:1:1. Holoenzyme contains an additional subunit sigma of 80 000 molecular weight (molar subunit composition alpha2 betabeta' sigma) and two relatively small polypeptides (molecular weight 14 000 and 25 000, respectively). Subunit sigma may be isolated from holoenzyme by chromatography on DEAE-cellulose at pH 6.9 in the presence of low concentrations of glycerol. The behaviour of holoenzyme during sedimentation in a glycerol gradient at low ionic strength indicates its occurrence as a dimer of the alpha2betabeta'sigma-protomer, whereas the monomeric form is preferred by core enzyme. Holoenzyme is much more active than core enzyme in RNA synthesis on bacteriophage T4DNA as template. The activity of the latter is stimulated by isolated sigma. M. luteus sigma as well as holoenzyme enhances also the activity of core enzyme fro- Escherichia coli. The formation of a hybrid between micrococcal sigma and E. coli core polymerase is also suggested by the influence of sigma on the oligomerisation of the enzyme from E. coli.
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PMID:Purification and characterization of the DNA-dependent RNA polymerase and its subunit sigma from Micrococcus luteus. 59 Sep 42

HeLa nuclear homogenates incubated in vitro incorporate [beta-32P]ATP and S-[methyl-3H]-adenosylmeth-ionine ([3H]SAM) into blocked methylated 5' termini of newly synthesized RNA. Approximately 10% of the RNA chains initiated in vitro with [beta-32P]ATP are subsequently blocked by condensation of GMP to di- or triphosphate terminated RNA. The blocked termini can then be methylated by transfer of methyl groups from [3H]SAM to the 7 position of the guanosine and 2'-O position of the adenosine to form m7Gpp*pAm- capped terminus. In addition to conventional triphosphate caps, HeLa nuclear homogenates produce capping structures containing two phosphate residues in the pyrophosphate bridge. The two distinct cap forms were separated by DEAE-cellulose chromatography and analyzed. In contrast to triphosphate caps (m7GpppXm) in which X can be any one of the four nucleosides (G, A, C, or U), in diphosphate caps (m7GppXm), more than 95% of the penultimate nucleoside Xm is G. Incorporation of both [beta-32P]ATP and [3H]SAM into caps was markedly reduced by low concentrations of alpha-amanitin. However, an ammonium sulfate fraction of the nuclear homogenate can cap beta-32P-labeled RNA (pp*pA-RNA) to form m7Gpp*pA-RNA, in the presence of 0.5 microgram/mL of alpha-amanitin. Therefore, the nuclear capping enzyme is resistant to this drug. Our results indicate that RNA polymerase II primary transcripts are the substrate for the cellular capping enzyme and that the beta phosphate in the pyrophosphate bridge (m7GgammapbetapalphapXm) is derived from the 5' ends of the RNA chains.
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PMID:Methylation and capping of RNA polymerase II primary transcripts by HeLa nuclear homogenates. 62 55

DNA-dependent RNA polymerase core enzyme was isolated from Halobacterium halobium. The purification is based on the finding that the enzyme is stable in 40% (v/v) glycerol, in the presence of 0.05 M MgCl2 and involves adsorption of contaminants to DEAE-cellulose, precipitation of the complex of polymerase with DNA by streptomycin sulfate, chromatography over Biogel and affinity chromatography over heparin-Sepharose or heparin-cellulose. The enzyme consists of four or five different subunits. The composition formula was estimated as (150000) (86000)2 (72000)2 (49000)3 or 2; there may be one or two different 49000-Mr subunits. RNA synthesis requires a template. Denatured DNA is more efficient than native DNA. The transcription of native DNA is specifically stimulated by the addition of a possibly sigma-like factor eluted from DEAE-cellulose. The fidelity of transcription is indicated by the absolute requirement for UTP besides ATP with poly[d(A-T)] as the template.
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PMID:DNA-dependent RNA polymerase from Halobacterium halobium. 72 Mar 36

A procedure has been developed for the rapid purification of large amounts of yeast RNA polymerase I (A). The method involves batchwise treatment with phosphocellulose and DEAE-cellulose, ion filtration chromatography on DEAE-Sephadex, sucrose gradient centrifugation, and DNA-cellulose chromatography. The enzyme obtained is apparently homogeneous by sedimentation velocity analysis and has a specific activity of 300 nmol of UMP incorporated into RNA in 10 min per mg of protein. Between 30 and 45 mg of enzyme can be obtained in 5 days from 3.0 kg of yeast cells. The subunit composition of the enzyme was determined by polyacrylamide gel electrophoresis in the presence of 0.1% sodium dodecyl sulfate. The purified polymerase is composed of 11 putative subunits with molecular weights 185,000 (Ia), 137,000 (Ib), 48,000 (Ic), 44,000 (Id), 41,000 (Ie), 36,000 (If), 28,000 (Ig), 24,000 (Ih), 20,000 (Ii), 14,500 (Ij), and 12,000 (Ik). Yeast polymerase I separates into two forms when subjected to gel electrophoresis under nondenaturing conditions. The main component which migrates faster contains all the subunits except the polypeptides Ic and If. The slow migrating component which is present in lower amounts contains all the subunits.
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PMID:Yeast DNA-dependent RNA polymerase I. A rapid procedure for the large scale purification of homogeneous enzyme. 76 34

The subunits of yeast RNA polymerases A(I) and B(II) were characterized using several techniques. The present studies demonstrate that the A and B enzymes possess three subunits, which are indistinguishable on the basis of molecular weight, isoelectric point, and fingerprint pattern. The three common subunits belong to the small molecular weight components of the enzymes. By polyacrylamide gel electrophoresis with sodium dodecyl sulfate they migrate with apparent molecular weights of 27,000, 23,000, and 14,500, respectively. A two-dimensional subunit mapping technique on polyacrylamide gel was used to separate the subunits according to isoelectric point and molecular weight. The common polypeptides co-migrated on three spots corresponding to isoelectric points of 9.2 (27,000), 4.5 (23,000), and 4.6 (14,500). The fingerprints of the 35S-labeled tryptic peptides of the presumptive common subunits were found to be essentially identical. Finally, the presence of common subunits was supported by the fact that antibodies against pure RNA polymerase A cross-react with and inhibit RNA polymerase B. Except for the common subunits, it is likely that RNA polymerases A and B are primarily made of distinct gene products for the following reasons. A total of 13 polypeptide chains are present in enzyme A, whereas 10 polypeptides are found in enzyme B. The molecular weight, isoelectric point, and sulfur content of the majority of these polypeptide chains are different in the two enzymes. No similarity was found in the 35S-peptide fingerprint from a number of A and B subunits of slightly different molecular weight. Finally, antibodies against the largest subunit from RNA polymerase A do not cross-react with or inhibit RNA polymerase B. The data are discussed in terms of structural organization of eukaryotic RNA polymerases.
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PMID:Structural studies on yeast RNA polymerases. Existence of common subunits in RNA polymerases A(I) and B(II). 76 38

Homogeneous RNA polymerase III (RNA nucleotidyltransferase III) has been obtained from yeast. The subunit composition of the enzyme was examined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The enzyme is composed of 12 putative subunits with molecular weights 160,000, 128,000, 82,000, 41,000, 40,500, 37,000, 34,000, 28,000, 24,000, 20,000, 14,500, and 11,000. The high-molecular-weight subunits and several of the smaller subunits of yeast RNA polymerase III are clearly different from those of enzymes I and II, indicating a distinct molecular structure. However, the molecular weights of some of the small subunits (41,000, 28,000, 24,000, and 14,500) appear to be identical to those of polymerases I and II. Thus, it is possible that the three classes of enzymes in yeast have some common subunits. As in other eukaryotes, yeast polymerase II is inhibited by relatively low concentrations of alpha-amanitin; however, contrary to what has been found in higher eukaryotes, yeast polymerase III is resistant (up to 2 mg/ml) to alpha-amanitin, while yeast polymerase I is sensitive to high concentrations of the drug (50% inhibition at 0.3 mg/ml). These results establish the existence of RNA polymerase III in yeast and provide a structural basis for the discrimination of the three functional polymerases in eukaryotes.
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PMID:Molecular structure of yeast RNA polymerase III: demonstration of the tripartite transcriptive system in lower eukaryotes. 77 75

Three peaks of DNA-dependent RNA polymerase (RNA nucleotidyltransferase) activity are resolved by chromatography of a sonicated yeast cell extract on DEAE-Sephadex. The enzymes, which are named RNA polymerases I, II, and III in order of elution, show similar catalytic properties to the vertebrate class I, class II, and class III RNA polymerases, respectively. Yeast RNA polymerase III is readily distinguished from yeast polymerase I by its biphasic amnonium sulfate activation profile with native DNA templates, greater enzymatic activity with poly[d(I-C)] than with native salmon sperm DNA, and distinctive chromatographic elution positions from DEAE-cellulose (0.12 M ammonium sulfate) compared with DEAE-Sephadex (0.32 M ammonium sulfate). The three yeast RNA polymerases also show significant differences in alpha-amanitin inhibition. RNA polymerase II is the most sensitive (50% inhibition at 1.0 mug of alpha-amanitin per ml). Contrary to the results for vertebrate systems, yeast polymerase I can be completely inhibited by alpha-amanitin at high concentrations (50% inhibition at 600 mug/ml) while yeast RNA polymerase II BEGINS TO SHOW SIGNIFICANT INHIBITION ONLY AT CONCENTRATIONS EXCEEDING 1 MG/ML. Therefore, yeast RNA polymerases I and III show a pattern of alpha-amanitin sensitivity that is the reverse of that seen for the analogous vertebrate RNA polymerases.
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PMID:Transcription in yeast: alpha-amanitin sensitivity and other properties which distinguish between RNA polymerases I and III. 77 76

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