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)

We examined the role of transcription in directing repair of DNA damage in active genes by comparing the repair of thymine glycols produced by H2O2 and of UV-induced pyrimidine dimers on each strand of the GAL7 gene of Saccharomyces cerevisiae. Repair of both thymine glycols and pyrimidine dimers on the transcribed strand of the gene occurs two to three times faster than on its nontranscribed strand or in the genome overall. When the gene is inactive, no preferential or strand-selective repair is observed. Using a yeast strain containing a temperature-sensitive mutation in one of the subunits of RNA polymerase II, we find that inactivating RNA polymerase II by shifting the cells to the nonpermissive temperature during repair eliminates the strand selectivity of repair under conditions where repair on the nontranscribed strand of the gene and in the genome overall are only slightly affected. Our observation of strand-selective repair of thymine glycols in the GAL7 gene is the first evidence that this repair process occurs for a nonbulky lesion. In addition, we demonstrate that the transcriptional complex plays a critical role in directing repair to the transcribed strand of active genes.
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PMID:Strand-selective repair of DNA damage in the yeast GAL7 gene requires RNA polymerase II. 142 64

While preferential repair of the transcribed strands within active genes has been demonstrated in organisms as diverse as humans and Escherichia coli, it has not previously been shown to occur in chromosomal genes in the yeast Saccharomyces cerevisiae. We found that repair of cyclobutane pyrimidine dimers in the transcribed strand of the expressed RPB2 gene in the chromosome of a repair-proficient strain is much more rapid than that in the nontranscribed strand. Furthermore, a copy of the RPB2 gene borne on a centromeric ARS1 plasmid showed the same strand bias in repair. To investigate the relation of this strand bias to transcription, we studied repair in a yeast strain with the temperature-sensitive mutation, rpb1-1, in the largest subunit of RNA polymerase II. When exponentially growing rpb1-1 cells are shifted to the nonpermissive temperature, they rapidly cease mRNA synthesis. At the permissive temperature, both rpb1-1 and the wild-type, parental cells exhibited rapid, proficient repair in the transcribed strand of chromosomal and plasmid-borne copies of the RPB2 gene. At the nonpermissive temperature, the rate of repair in the transcribed strand in rpb1-1 cells was reduced to that in the nontranscribed strand. These findings establish the dependence of strand bias in repair on transcription by RNA polymerase II in the chromosomes and in plasmids, and they validate the use of plasmids for analysis of the relation of repair to transcription in yeast.
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PMID:Preferential repair of cyclobutane pyrimidine dimers in the transcribed strand of a gene in yeast chromosomes and plasmids is dependent on transcription. 143 66

The sugar boronated thymidine nucleoside, 5' -0-[(triphenylphosphine-boryl) carbonyl]-3'-0-acetyl thymidine 1, and the boron-modified nucleoside phosphotriester, 5'-(diethylphosphite- cyanoborane)-3'-acetylthymidine 2, were successfully synthesized. Both compounds demonstrated differential activity when tested against eight cell lines, with significant cytotoxic activity against the growth of human Tmolt3 leukemia, colon adenocarcinoma, HeLa S3 uterine carcinoma, and osteosarcoma cells. In in vivo studies these agents were found to be active against the growth of Ehrlich ascites carcinoma at 8 mg/kg/day I.P. and to be marginally active against the growth of L1210 and Lewis lung cancers in mice. The mode of action of these thymidine derivatives in Tmolt3 cells was the inhibition of DNA and protein synthesis. Compound 2 was highly effective in inhibiting DNA polymerase alpha and m-RNA, r-RNA and t-RNA polymerase activities. Both compounds inhibited ribonucleoside reductase activity. The de novo purine pathway appeared to be the major site of inhibition of the agents, with IMP dehydrogenase, PRPP amido transferase, and dihydrofolate reductase activities being significantly inhibited. In the pyrimidine pathway, carbamyl phosphate synthetase and aspartate transcarbamylase activities were inhibited by 1. As expected, d[NTP] levels were significantly reduced by treatment with the agents. DNA strand scission was evident after incubating Tmolt3 cells for 24 hr with the agents.
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PMID:Antineoplastic activity of boron-containing thymidine nucleosides in Tmolt3 leukemic cells. 150 1

An experimental approach is presented for the creation of an artificial and functional repressor/operator interaction that does not involve polypeptides. This in vitro approach confers oligonucleotide regulation upon a bacteriophage T7 RNA polymerase promoter by introducing an overlapping homopurine operator that can be recognized by oligonucleotide-directed DNA triple-helix formation. Recognition of optimized operator sequences in either of two triple-helix motifs is shown to efficiently inhibit T7 RNA polymerase transcription initiation in both a promoter- and oligonucleotide-specific manner. Inhibition due to triple helices of the pyrimidine motif is pH-dependent, as expected. Inhibition by purine motif triple helices is not pH-dependent and occurs efficiently under optimum T7 RNA polymerase transcription conditions. Repression by triple-helix formation can be observed rapidly after addition of purine motif repressor oligonucleotides, even when polymerase has been given prior access to the promoter. The mechanism of repression is shown to be occlusion of polymerase from the promoter rather than trapping of the polymerase in unproductive preinitiation or initiation complexes. In contrast to their inhibition of T7 RNA polymerase initiation, the triple-helical complexes studied here do not detectably inhibit transcription elongation.
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PMID:Inhibition of T7 RNA polymerase initiation by triple-helical DNA complexes: a model for artificial gene repression. 151 Sep 45

In this work, we attempted to gain insight into the detailed mechanism allowing correct transcription initiation of U1 snRNA genes by RNA polymerase II. Abolition of the CA motif residing at -1/+1 in the Xenopus U1 gene leads to a loss of the ability of the promoter to direct accurate initiation. A discrete site is selected only if a purine preceded by a pyrimidine is positioned at 58/57 bp downstream of the center of the PSE. The PSE alone is unable to designate a discrete initiation site. Rather, it serves to set the location of an initiation window without discriminating suitable from unsuitable initiation sites. The latter role is devoted to a PyPu sequence positioned at -1/+1. Therefore, it is the concomitant action of the PSE and an essential PyPu positioned at the proper distance from this promoter that specifies correct U1 snRNA transcription initiation by RNA polymerase II.
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PMID:The proximal promoter and the start site cooperate to specify correct U1 snRNA transcription initiation by RNA polymerase II. 157 49

The action of rifampicin on the RNA chain initiation catalysed by E. coli RNA polymerase over different templates has been studied. The steady-state formation of dinucleoside tetraphosphate under the condition of abortive initiation reaction was assayed. It was observed that rifampicin shows a spectrum of inhibitory effects on transcription initiation at different promoters. At two different promoters with a pyrimidine nucleotide at the 5'-initiation site, e.g. rrnB P2 having CTP and lacP2 having UTP, the effect of rifampicin on the abortive synthesis of the first phosphodiester bond was found to be total, even at low concentrations of the antibiotic. On the other hand, in most cases the effect of rifampicin on the abortive synthesis with a purine nucleotide at the 5'-initiation site was found to be only partial, with the exception of the T7A2 promoter, where rifampicin stimulates the abortive synthesis of pppGpC. It was also noticed that if there was a purine nucleotide at the second position of a dinucleotide which had already been synthesised by the enzyme, then further addition of the third nucleotide was not blocked in the presence of rifampicin. It appeared that a purine nucleotide at the initiation site or at the product terminus site of a translocated dinucleotide behaved similarly towards rifampicin. In the same way, if this position was occupied by a pyrimidine, rifampicin would inhibit further phosphodiester synthesis, even at a very low concentration. The stimulatory effect of rifampicin at the T7A2 promoter was presumably because here a ternary complex containing the promoter, enzyme and the abortive transcript pppGpC was initially stable, but dissociated upon addition of rifampicin, resulting in the rapid turn-over of the product.
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PMID:Differential inhibition of abortive transcription initiation at different promoters catalysed by E. coli RNA polymerase. Effect of rifampicin on purine or pyramidine-initiated phosphodiester synthesis. 162 42

A polyacrylamide gel assay is used to measure the kinetics of adding a single deoxyribonucleotide onto either a correctly matched or mismatched primer 3' terminus (on M13 template) for all possible DNA base pairs and mispairs using Drosophila melanogaster DNA polymerase alpha (Pol alpha) and avian myeloblastosis virus reverse transcriptase. The reverse transcriptase catalyzes chain extension from transition mispairs (Pur.Pyr and Pyr.Pur, where Pur is purine and Pyr is pyrimidine) more efficiently than polymerase alpha. Reverse transcriptase extends G(primer).T almost 20% as efficiently as it extends A.T, while Pol alpha's G.T extension efficiency is less than 1%. For transversion mispairs (Pur.Pur and Pyr.Pyr), reverse transcriptase extends C.T and T.T with greater efficiency than polymerase alpha, while polymerase alpha is more efficient at extending A.G and G.G mispairs. Reverse transcriptase and polymerase alpha extend the G.G mispair at an efficiency of only 10(-6) and 10(-5), respectively, compared with G.C extension. The extension data for the two polymerases are compared with previously reported nucleotide misinsertion data for the same enzymes (Mendelman, L. V., Boosalis, M. S., Petruska, J., and Goodman, M. F. (1989) J. Biol. Chem. 264, 14415-14423). While the results obtained with reverse transcriptase and Pol alpha differ in detail, some general rules are indicated: (a) Pur.Pyr and Pyr.Pur mispairs, especially G.T and T.G, are easy to insert and even easier to extend; (b) Pyr.Pyr mispairs, especially C.C, are difficult to insert and slightly easier to extend; (c) Pur.Pur mispairs, notably G.G, are harder to extend than to insert. The comparison also shows that reverse transcriptase extends almost all mismatches more efficiently than it forms them, G.G being the only mismatch having a significantly lower efficiency of extension than insertion. Polymerase alpha inserts A.A mismatches most efficiently, but extends them inefficiently, thereby reducing the probability that such transversion mutations will occur in vivo. We show theoretically that when mispaired primers compete with properly matched primers for extension by polymerase, the relative velocities of extension depend on the concentration of the next correct dNTP substrate. The extension velocities depart from Michaelis-Menten kinetics by exhibiting positive cooperativity with respect to substrate concentration.
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PMID:Base mispair extension kinetics. Comparison of DNA polymerase alpha and reverse transcriptase. 168 52

A complete cell cycle of mature, concanavalin A (Con A) stimulated rat thymocytes was documented by analyzing the cell number as well as the content and synthesis of DNA and RNA. Cell cycle progression is accompanied by an elevation of class I, II and III RNA polymerase activities (about 10-fold) in the S phase maximum, 48 h after stimulation. Moreover, maximal cellular contents of DNA, ATP, ADP and AMP were observed at this culture period, whereas the RNA level peaked at 60 h. The synthesis of purine and pyrimidine nucleotides de novo was detected by use of [14C]HCO3-. Maximal incorporation rates of [14C]HCO3- into nucleotides (de novo synthesis) and of [3H]adenine into adenylates ('salvage pathway') occur during the S phase. However, the de novo synthesis rates were markedly lower than those of the 'salvage pathway'. The highest cellular level of the nucleotide precursor 5-phosphoribosyl-1-pyrophosphate (8.4-fold increase) also coincided with the S phase.
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PMID:Nucleotide and nucleic acid metabolism in rat thymocytes during cell cycle progression. 171 37

Excision-deficient haploid yeast cells (Saccharomyces cerevisiae) were exposed to 254-nm UV radiation and protein synthesis inhibition was measured for a large number of different proteins resolved by two-dimensional gel electrophoresis. The derived UV-radiation sensitivities exhibited an overall increase with protein molar mass. Quantitatively, this behavior is compatible with a well known mechanism of transcription inactivation--termination of RNA chains at UV-radiation-induced pyrimidine dimers--if the respective target sizes are inferred from protein molar mass. The observed deviations from the predicted response suggest that (i) UV-radiation damage may also interfere with recognition/binding of RNA polymerase to regulatory sequences and (ii) the frequency of photolesions for a specific protein encoding gene may differ markedly from the mean induction rate for the total yeast genome.
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PMID:Protein synthesis in irradiated cells. I. Ultraviolet radiation. 173 48

To identify the DNA sequences required for initiation of transcription in archaea, the 5'-flanking region of the tRNA(Val) gene of Methanococcus vannielii was modified by deletions, restructuring and site-directed mutagenesis, and the tRNA encoding sequence was replaced by a fortuitous Escherichia coli sequence. The effects of these mutations on promoter function were tested in an homologous cell-free transcription system. The DNA region from position -35 to +9 relative to the transcription start site was sufficient for maximal initiation of cell-free transcription. Removal of the DNA region between -35 and -30 reduced initiation by a factor of 2. Deletions extending to position -24 almost completely abolished specific transcription. Analysis of 16 site-specific mutations in the region from -33 to +2 provided evidence that a conserved A + T-rich sequence (TATA box), centered at -25, is essential for initiation of transcription. Single point mutations in six positions of the TATA box reduced initiation of transcription from 0.2 to 0.01 of wild-type levels. A second conserved motif at the transcription start site (consensus ATGC) could be replaced by some sequences containing a pyrimidine-purine dinucleotide but appeared necessary for a maximal rate of gene transcription. Mutations altering the spacing between the two conserved elements demonstrated that initiation occurs at a strictly defined distance of 22 to 27 base-pairs downstream from the TATA box. Our results support the conclusion that the TATA box is the major DNA region mediating promoter recognition, influencing the efficiency of transcription and specifying the site of transcription initiation. This Methanococcus promoter element closely resembles in structure and function the TATA box of promoters of eukaryotic protein-encoding genes transcribed by RNA polymerase II.
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PMID:Control regions of an archaeal gene. A TATA box and an initiator element promote cell-free transcription of the tRNA(Val) gene of Methanococcus vannielii. 174 92

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