EC:2.7.7.6 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The protein components that direct and activate accurate transcription by rat RNA polymerase I were studied in extracts of Novikoff hepatoma ascites cells. A minimum of at least two components, besides RNA polymerase I, that are necessary for efficient utilization of templates were identified. The first factor, rat SL-1, is required for species-specific recognition of the rat RNA polymerase I promoter and may be sufficient to direct transcription by pure RNA polymerase I. Rat SL-1 directed the transcription of templates deleted to -31, the 5' boundary of the core promoter element (+1 being the transcription initiation site). The second factor, rUBF, increased the efficiency of template utilization. Transcription of deletion mutants indicated that the 5' boundary of the domain required for rUBF lay between -137 and -127. Experiments using block substitution mutants confirmed and extended these observations. Transcription experiments using those mutants demonstrated that two regions within the upstream promoter element were required for optimal levels of transcription in vitro. The first region was centered on nucleotides -129 and -124. The 5' boundary of the second domain mapped to between nucleotides -106 and -101. DNase footprint experiments using highly purified rUBF indicated that rUBF bound between -130 and -50. However, mutation of nucleotides -129 and -124 did not affect the rUBF footprint. These results indicate that basal levels of transcription by RNA polymerase I may require only SL-1 and the core promoter element. However, higher transcription levels are mediated by additional interactions of rUBF, and possibly SL-1, bound to distal promoter elements.
...
PMID:Characterization of factors that direct transcription of rat ribosomal DNA. 234 70

We have prepared three types of RNA polymerase II transcription complexes: a preinitiation complex (complex 0), a complex which has synthesized two phosphodiester bonds (complex 2), and a complex which has synthesized 10-13 bonds (complex 10). We have studied the differential response of these complexes to a variety of disruptions: detergent (Sarkosyl), high levels of KCl, extended incubation at 25 degrees C, proteolysis, and digestion with DNase I. Complex 0 is extremely stable at 25 degrees C in the absence of ATP, but it is sensitive to the other treatments including 25 degrees C incubation in the presence of ATP. Once the complex has made two phosphodiester bonds, the properties almost reverse from those of complex 0; complex 2 remains unstable at 25 degrees C in the presence of ATP but is resistant to high levels of Sarkosyl and KCl, to extensive DNase I digestion, and to brief proteolysis. Addition of 10 or more bases to the growing RNA chain results in a complex completely resistant to all of the treatments used. When DNase I-trimmed complex 0 is allowed to initiate RNA synthesis, chains of about 33 bases are obtained. In contrast, DNase-trimmed complex 2 gives only about 23 base transcripts; DNase-treated complex 10 will elongate its nascent chains by about 21 bases as well (to give, on average, 34 base transcripts).
...
PMID:Transcription initiation by RNA polymerase II in vitro. Properties of preinitiation, initiation, and elongation complexes. 243 61

We have used an Eppendorf centrifuge for isolation of transcription complexes assembled on VARNA genes and other related genes with NTP-depleted cell-free extracts. Similar to the 5 S rRNA gene, sedimentable, stable transcription preinitiation complexes could be assembled from two VARNA genes, two EB virus-specific EBER genes, four human tRNA genes, and one human Alu-family RNA gene, suggesting that the 5 S rRNA-specific transcription factor, TFIIIA, was not required for formation of these sedimentable, stable preinitiation complexes. Parameters affecting assembly of these complexes were sequences in circular DNA templates, sizes and sequences of linear DNA templates, temperature and incubation time. These complexes were stable at from 4 to 37 degrees C, and somewhat stable to salt wash. From results of effects of various mutations on assembly of these sedimentable complexes, we concluded that they were transcription machineries. Addition of the supernatant and partially purified factors to salt-washed complexes stimulated their transcription, we concluded that these sedimentable complexes were minimal transcription machineries containing suboptimal quantities of loosely bound transcription factors, TFIIIB, and RNA polymerase III. DNase 1 footprints of these sedimentable preinitiation complexes showed that two regions were protected, from +34 to +80 including the B block promoter element, and from +98 to +105. Similar DNase 1 footprints were also obtained from salt-washed complexes and stable preinitiation complexes isolated by molecular sieve column chromatography.
...
PMID:Formation of large, sedimentable transcription complexes with VARNA genes and other related genes. 272 76

Yeast transcription factor tau forms a stable complex with tRNA genes. Using this property, the factor could be highly purified on a specific tDNA column. The purified factor was found by DNA footprinting to protect the whole yeast tRNA3Glu gene from position -8 to +81. A DNase-sensitive site was retained in the middle of the gene on both strands. The 3' border of the complex was mapped by exonuclease digestion at +88, just downstream of the termination signal. The 5' limit of the complex was found at position -11. However, upon prolonged incubation with exonuclease, the -11 blockage disappeared and the DNA molecules were digested to position +30 to 38 in the middle of the gene. Contact points at guanine residues were identified by dimethyl sulphate protection experiments. Reduced methylation of G residues in the presence of factor was found solely within the A block and in the B block region. All six invariant GC pairs (i.e., G10, G18, G19 and G53, C56 and C61) were found to have strong contacts with the factor. These results show that tau factor interacts with both the 5' and 3' half of the tRNA3Glu gene, with the B block region being the predominant binding site. The presence of this dual binding site suggests a model in which the factor would bind alternately at the A and B block regions to allow transcription of the internal promoter by RNA polymerase C.
...
PMID:A split binding site for transcription factor tau on the tRNA3Glu gene. 286 29

The plasmid-encoded replication initiator protein of pSC101 specifically repressed initiation of transcription of its own cistron from its natural promoter. Addition of the purified initiator had little or no visible effect on transcription initiated from a heterologous promoter. DNase protection experiments revealed that the RNA polymerase recognition sequence was overlapped by the initiator protein recognition sequences, which are vicinal to the replication origin. Using the labeled promoter sequence, we have performed competitive DNase protection experiments in two ways: by adding RNA polymerase and initiator protein simultaneously or by sequentially adding first RNA polymerase and then initiator protein to the DNase reaction mixture. The RNA polymerase protection pattern was recessive to that of the initiator regardless of whether the two proteins were added simultaneously or sequentially. This observation suggests that the mechanism of autoregulation is due to competition of the two proteins for the sequences in and around the promoter region. Furthermore, the sequential addition experiments raise the possibility of displacement of RNA polymerase from the promoter by the initiator protein.
...
PMID:The replication initiator protein of plasmid pSC101 is a transcriptional repressor of its own cistron. 298 8

Replication of the infectious RNA genome of poliovirus is accomplished in cells by the viral RNA polymerase through negative-strand RNA intermediates. Full-length negative-strand poliovirus RNA was synthesized in vitro by transcription of infectious poliovirus cDNA with bacteriophage SP6 DNA-dependent RNA polymerase. When provided with this negative-strand RNA as template, the poliovirus RNA-dependent RNA polymerase synthesized full-length positive-strand molecules. The positive-strand RNAs synthesized in vitro were infectious when transfected into HeLa cells. In contrast, positive-strand copies of poliovirus RNA synthesized in vitro by SP6 polymerase, using a poliovirus cDNA template, were not infectious. Production of infectious positive-strand RNA by the poliovirus polymerase was not observed when magnesium or negative-strand RNA template was omitted from the reaction mixture. Infectivity of the product RNA was not destroyed by DNase treatment. The specific infectivity in HeLa cells of in vitro-synthesized positive-strand RNA was 4 X 10(4) plaque-forming units/micrograms of RNA.
...
PMID:In vitro synthesis of infectious poliovirus RNA. 300 3

A high-molecular-weight protein complex that is capable of accurate transcription initiation and termination of vaccinia virus early genes without additional factors was demonstrated. The complex was solubilized by disruption of purified virions, freed of DNA by passage through a DEAE-cellulose column, and isolated by glycerol gradient sedimentation. All detectable RNA polymerase activity was associated with the transcription complex, whereas the majority of enzymes released from virus cores including mRNA (nucleoside-2'-O)methyltransferase, poly(A) polymerase, topoisomerase, nucleoside triphosphate phosphohydrolase II, protein kinase, and single-strand DNase sedimented more slowly. Activities corresponding to two enzymes, mRNA guanylyltransferase (capping enzyme) and nucleoside triphosphate phosphohydrolase I (DNA-dependent ATPase), partially sedimented with the complex. Silver-stained polyacrylamide gels, immunoblots, and autoradiographs confirmed the presence of subunits of vaccinia virus RNA polymerase, mRNA guanylyltransferase, and nucleoside triphosphate phosphohydrolase I, as well as additional unidentified polypeptides, in fractions with transcriptase activity. A possible role for the DNA-dependent ATPase was suggested by studies with ATP analogs with gamma-S or nonhydrolyzable beta-gamma-phosphodiester bonds. These analogs were used by vaccinia virus RNA polymerase to nonspecifically transcribe single-stranded DNA templates but did not support accurate transcription of early genes by the complex. Transcription also was sensitive to high concentrations of novobiocin; however, this effect could be attributed to inhibition of RNA polymerase or ATPase activities rather than topoisomerase.
...
PMID:Sedimentation of an RNA polymerase complex from vaccinia virus that specifically initiates and terminates transcription. 303 83

A DNA-dependent RNA polymerase was solubilized from sucrose gradient isolated, DNase-treated mitochondria of Drosophila melanogaster. The isolated mitochondria were not detectably contaminated with nuclear DNA as shown by CsCl gradient centrifugation and polylysine Kieselguhr chromatography. The detergent-solubilized RNA polymerase was sensitive to rifampicin, resistant to alpha-amanitin, had an apparent molecular mass of about 60 kilodaltons, and displayed a tendency to aggregate, both in crude extracts or when purified. The mitochondrial RNA polymerase could be distinguished from nuclear RNA polymerases on the basis of size, salt optima, rifampicin sensitivity, and alpha-amanitin resistance.
...
PMID:Isolation and characterization of a mitochondrial RNA polymerase from Drosophila melanogaster. 310 54

A phosphocellulose flowthrough fraction required for accurate transcription in vitro by RNA polymerase II was found to contain a DNase inhibitor which was necessary to maintain template integrity (Price D.H., Sluder A.E. & Greenleaf A.L. (1987) J. Biol. Chem. 262, 3244-3255). Starting with a Drosophila Kc cell nuclear extract, the DNase inhibitory activity has been purified 19,000-fold. In combination with the other necessary fractions, the highly purified inhibitor continues to support reconstruction of transcription. It thus appears to be the only required activity in the original phosphocellulose flowthrough fraction. The inhibitor is a protein which does not bind to DNA or inhibit DNase I, so that it has also been useful in assays for DNA binding proteins in crude, DNase-contaminated fractions.
...
PMID:An activity necessary for in vitro transcription is a DNase inhibitor. 312 25

A minimal mechanism is proposed which describes the transcriptional and translational processes for four phage proteins (RNA polymerase, DNase, primase and DNA polymerase) involved in T3/T7 DNA replication. Phage DNA replication is also included. It is shown how lag times may be incorporated into a kinetic mechanism. The distinct three-stage transport of phage DNA into the bacterial host (E. coli) is considered. DNA transport is assumed to be rate-determining for the transcription of class I and II proteins. Transcriptional and translational lag times have been calculated on the basis of available gene mapping of T7 phages. The kinetic behavior of T7 and T3 phage infection is practically identical. The hydrolysis of bacterial DNA by phage DNase (endonculease and exonuclease) as well as the subsequent phosphorylation to the deoxymononucleoside triphosphates are assumed to be rate-determining in phage DNA replication. Good agreement with experiment is obtained in our computer simulations.
...
PMID:Computer simulation of T3/T7 phage infection using lag times. 330 Aug 7

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>