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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

We have developed a method to isolate mutants of Saccharomyces cerevisiae that are primarily defective in the transcription of 35S ribosomal RNA (rRNA) genes by RNA polymerase I. The method uses a system in which the 35S rRNA gene is fused to the GAL7 promoter and is transcribed by RNA polymerase II under control of the GAL regulatory system. Chromosomal mutations affecting components specifically involved in synthesis of 35S rRNA by RNA polymerase I can be suppressed by this hybrid gene in the presence of inducer (galactose) but not in its absence. We looked for mutants the growth of which depended on the presence of plasmid expressing the hybrid gene. For this purpose, we used a red/white-colony color assay as the initial screen followed by a test for galactose-dependent growth. We have thus isolated many mutants and identified at least nine genes (RRN1-RRN9) involved in 35S rRNA synthesis, two of which correspond to known RNA polymerase I subunit genes RPA190 and RPA135.
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PMID:An approach for isolation of mutants defective in 35S ribosomal RNA synthesis in Saccharomyces cerevisiae. 187 Nov 18

The SRP3-1 mutation is an allele-specific suppressor of temperature-sensitive mutations in the largest subunit (A190) of RNA polymerase I from Saccharomyces cerevisiae. Two mutations known to be suppressed by SRP3-1 are in the putative zinc-binding domain of A190. We have cloned the SRP3 gene by using its suppressor activity and determined its complete nucleotide sequence. We conclude from the following evidence that the SRP3 gene encodes the second-largest subunit (A135) of RNA polymerase I. First, the deduced amino acid sequence of the gene product contains several regions with high homology to the corresponding regions of the second-largest subunits of RNA polymerases of various origins, including those of RNA polymerase II and III from S. cerevisiae. Second, the deduced amino acid sequence contains known amino acid sequences of two tryptic peptides from the A135 subunit of RNA polymerase I purified from S. cerevisiae. Finally, a strain was constructed in which transcription of the SRP3 gene was controlled by the inducible GAL7 promoter. When this strain, which can grow on galactose but not on glucose, was shifted from galactose medium to glucose medium, a large decrease in the cellular concentration of A135 was observed by Western blot analysis. We have also identified the specific amino acid alteration responsible for suppression by SRP3-1 and found that it is located within the putative zinc-binding domain conserved among the second-largest subunits of eucaryotic RNA polymerases. From these results, it is suggested that this putative zinc-binding domain is in physical proximity to and interacts with the putative zinc-binding domain of the A190 subunit.
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PMID:Suppressor analysis of temperature-sensitive mutations of the largest subunit of RNA polymerase I in Saccharomyces cerevisiae: a suppressor gene encodes the second-largest subunit of RNA polymerase I. 199 Feb 81

The 35S rRNA gene of the yeast Saccharomyces cerevisiae was fused to the GAL7 promoter. This hybrid gene, when present on a multicopy plasmid and induced by galactose, suppressed the growth defects of a temperature-sensitive RNA polymerase I (pol I) mutant and those of a mutant in which the gene for the second largest subunit of pol I was deleted. Analysis of pulse-labeled RNA directly demonstrated that rRNA synthesis in this deletion mutant is from the GAL7 promoter. These experiments show that the sole essential function of pol I is the transcription of the rRNA genes, that pol I is not absolutely required for the synthesis of rRNA and ribosomes or cell growth if 35S rRNA synthesis is achieved by some other means, and that the tandemly repeated structure of the chromosomal rRNA genes is also not absolutely required for the synthesis of rRNA and ribosomes.
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PMID:Synthesis of large rRNAs by RNA polymerase II in mutants of Saccharomyces cerevisiae defective in RNA polymerase I. 202 44

We have identified a signal sequence (designated core signal) necessary to specify formation of mRNA 3' end of the GAL7 gene in Saccharomyces cerevisiae within a DNA segment 26 bp long. The sequence was located 4-5 nucleotides upstream from the 3' end, i.e. the polyadenylation site, of the GAL7 mRNA. Replacement of a DNA segment encompassing the polyadenylation site with a pBR322 DNA, leaving the core signal intact, resulted in alteration of the mRNA 3' end by several nucleotides, suggesting the existence of an additional signal (designated end signal) at or near the polyadenylation site. The normal end formation was abolished when the core signal was placed in the reverse orientation. A considerable fraction of pre-mRNA synthesized in vitro with SP6 RNA polymerase on the template of a DNA fragment containing these signals was cleaved and polyadenylated presumably at the in vitro 3' end during incubation in a cell-free system of yeast. By contrast pre-mRNA synthesized on the template with the core signal alone was processed but much less efficiently. No such processing was seen when the pre-mRNA either lacked the core signal or contained it in the reverse orientation.
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PMID:Signal sequence for generation of mRNA 3' end in the Saccharomyces cerevisiae GAL7 gene. 220 57

We have extended an earlier observation that the TATA box for the nuclear GAL10 gene serves as a promoter for the mitochondrial RNA polymerase in in vitro transcription reactions (C. S. Winkley, M. J. Keller, and J. A. Jaehning, J. Biol. Chem. 260:14214-14223, 1985). In this work, we demonstrate that other nuclear genes also have upstream sequences that function in vitro as mitochondrial RNA polymerase promoters. These genes include the GAL7 and MEL1 genes, which are regulated in concert with the GAL10 gene, the sigma repetitive element, and the 2 microns plasmid origin of replication. We used in vitro transcription reactions to test a large number of nuclear DNA sequences that contain critical mitochondrial promoter sequences as defined by Biswas et al. (T. K. Biswas, J. C. Edwards, M. Rabinowitz, and G. S. Getz, J. Biol. Chem. 262:13690-13696, 1987). The results of these experiments allowed us to extend the definition of essential promoter elements. This extended sequence, -ACTATAAACGatcATAG-, was frequently found in the upstream regulatory regions of nuclear genes. On the basis of these observations, we hypothesized that either (i) a catalytic RNA polymerase related to the mitochondrial enzyme functions in the nucleus of the yeast cell or (ii) a DNA sequence recognition factor is shared by the two genetic compartments. By using cells deficient in the catalytic core of the mitochondrial RNA polymerase (rpo41-) and sensitive assays for transcripts initiating from the nuclear promoter sequences, we have conclusively ruled out a role for the catalytic RNA polymerase in synthesizing transcripts from all of the nuclear sequences analyzed. The possibility that a DNA sequence recognition factor functions in both the nucleus and the mitochondria remains to be tested.
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PMID:Use of yeast nuclear DNA sequences to define the mitochondrial RNA polymerase promoter in vitro. 267 67

We developed an improved method for the isolation of transcriptionally active nuclei from Saccharomyces cerevisiae, which allows analysis of specific transcripts. When incubated with alpha-32P-labeled ribonucleoside triphosphates in vitro, nuclei isolated from haploid or diploid cells transcribed rRNA, tRNA, and mRNAs in a strand-specific manner, as shown by slot blot hybridization of the in vitro synthesized RNA to cloned genes encoding 5.8S, 18S and 28S rRNAs, tRNATyr, and GAL7, URA3, TY1 and HIS3 mRNAs. A yeast strain containing a high-copy-number plasmid which overproduced GAL7 mRNA was initially used to facilitate detection of a discrete message. We optimized conditions for the transcription of genes expressed by each of the three yeast nuclear RNA polymerases. Under optimal conditions, labeled transcripts could be detected from single-copy genes normally expressed at low levels in the cells (HIS3 and URA3). We determined that the alpha-amanitin sensitivity of transcript synthesis in the isolated nuclei paralleled the sensitivity of the corresponding purified RNA polymerases; in particular, mRNA synthesis was 50% sensitive to 1 microgram of alpha-amanitin per ml, establishing transcription of mRNA by RNA polymerase II.
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PMID:mRNA transcription in nuclei isolated from Saccharomyces cerevisiae. 353 8

Yeast RNA polymerase I contains 14 distinct polypeptides, including A43, a component of about 43 kDa. The corresponding gene, RPA43, encodes a 326-amino acid polypeptide matching the peptidic sequence of two tryptic fragments isolated from A43. Gene inactivation leads to a lethal phenotype that is rescued by a plasmid containing the 35S ribosomal RNA gene fused to the GAL7 promoter, which allows the synthesis of 35S rRNA by RNA polymerase II in the presence of galactose. A screening for mutants rescued by the presence of GAL7-35SrDNA identified a nonsense rpa43 allele truncating the protein at amino acid position 217. [3H]Uridine pulse labeling showed that this mutation abolishes 35S rRNA synthesis without significant effects on the synthesis of 5 S RNA and tRNAs. These properties establish that A43 is an essential component of RNA polymerase I. This highly hydrophilic phosphoprotein has a strongly acidic carboxyl-terminal domain, and shows no homology to entries in current sequence data banks, including all the genetically identified components of the other two yeast RNA polymerases. RPA43 mapped next to RPA190, encoding the largest subunit of polymerase I. These genes are divergently transcribed and may thus share upstream regulatory elements ensuring their co-regulation.
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PMID:Gene RPA43 in Saccharomyces cerevisiae encodes an essential subunit of RNA polymerase I. 759 32

The RAD25 gene of Saccharomyces cerevisiae is required for excision repair of ultraviolet-damaged DNA and, in addition, is essential for viability. RAD25 shares a high degree of homology with the human ERCC3/XPBC-encoded protein, and the yeast and human proteins resemble one another in containing the conserved ATPase/DNA helicase sequence motifs. To determine the nature of the essential role of RAD25, we have isolated a recessive temperature-sensitive conditional lethal mutation of the gene and have examined its effect on transcription. Upon shift to the nonpermissive temperature, the rad25 temperature-sensitive (ts) mutant stops growth rapidly and shows a large decrease in the synthesis of poly(A)+ RNA. Transcription of a large number of yeast genes, including HIS3, TRP3, STE2, MET19, RAD23, CDC9, and ACT1 is inhibited at the restrictive temperature in the rad25 ts mutant, and the galactose-inducible synthesis of GAL7 and GAL10 mRNAs is also severely affected by the loss of RAD25 activity. These findings implicate a general requirement of RAD25 in RNA polymerase II transcription.
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PMID:The Saccharomyces cerevisiae DNA repair gene RAD25 is required for transcription by RNA polymerase II. 769 49

We have developed a system for mutational analysis of Saccharomyces cerevisiae ribosomal RNA in vivo in which yeast cells can be made completely dependent on mutant rRNA and ribosomes by a simple switch in carbon source. The system is based on a yeast strain defective in RNA polymerase I (Pol I) transcription [Nogi et al. (1991) Proc. Natl. Acad. Sci. USA 88, 3962-3966]. This normally inviable strain was rescued by integration of multiple copies of the complete 37S pre-rRNA operon under control of the inducible, Pol II-transcribed GAL7 promoter into the rDNA repeat on chromosome XII. The resulting YJV100 strain can only grow on medium containing galactose as the carbon source. A second, episomal vector was constructed in which the rDNA unit was placed under control of the constitutive PGK1 promoter. YJV100 cells transformed with this vector are now also able to grow on glucose-based medium making the cells completely dependent on plasmid-encoded rRNA. We show that the Pol II-transcribed pre-rRNA is processed and assembled similarly to authentic Pol I-synthesised pre-rRNA, making this 'in vivo Pol II system' suitable for the detailed analysis of rRNA mutations, even highly deleterious ones, affecting ribosome biogenesis or function. A clear demonstration of this is our finding that an insertion into variable region V8 in 17S rRNA, previously judged to be neutral with respect to processing of 17S rRNA, its assembly into 40S subunits and the polysomal distribution of these subunits [Musters et al. (1989), Mol. Cell. Biol. 9, 551-559], is in fact a lethal mutation.
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PMID:Development and application of an in vivo system to study yeast ribosomal RNA biogenesis and function. 773 24

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