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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)

The gene encoding the 49-kDa subunit of RNA polymerase A in Saccharomyces cerevisiae has been identified by formation of a hybrid enzyme between the S. cerevisiae A49 subunit and Saccharomyces douglasii subunits based on a polymorphism existing between the subunits of RNA polymerase A in these two species. The sequence of the gene reveals a basic protein with an unusually high lysine content, which may account for the affinity for DNA shown by the subunit. No appreciable homology with any polymerase subunits, enzymes, or transcription factors is found. Complete deletion of the single-copy RPA49 gene leads to viable but slowly growing colonies. Insertion of the HIS3 gene halfway into the RPA49 coding region results in synthesis of a truncated A49 subunit that is incorporated into the polymerase. The truncated and wild-type subunits compete equally for assembly in the heterozygous diploid, although the wild type is phenotypically dominant.
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PMID:Characterization and mutagenesis of the gene encoding the A49 subunit of RNA polymerase A in Saccharomyces cerevisiae. 140 38

RPC53 has previously been shown to encode an essential subunit required for tRNA gene transcription by RNA polymerase C in vivo (Mann, C., Micouin, J.-Y., Chiannilkulchai, N., Treich, I., Buhler, J.-M., and Sentenac, A. (1992) Mol. Cell. Biol. 12, in press). In this paper, we have determined that an unusual rho+ lethality associated with the rpc53::HIS3-1 disruption mutation is due to the inadvertent formation of a Pet56-C53 fusion protein. This fusion protein is missorted to mitochondria, thereby reducing the quantity of the C53 subunit available for RNA polymerase C assembly. We show that the carboxyl-terminal region of C53 contains the essential functional domain of the subunit and that a mutant RNA polymerase containing only this domain is thermolabile for its function in vivo and in vitro. The thermolability of the carboxyl-terminal C53 domain is suppressed by five different genes on multicopy plasmids, including RPC160, encoding the largest subunit of RNA polymerase C and SSD1/SRK1, which has been implicated in the activity of protein phosphatases.
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PMID:Biochemical and genetic dissection of the Saccharomyces cerevisiae RNA polymerase C53 subunit through the analysis of a mitochondrially mis-sorted mutant construct. 142 57

We have previously reported on the isolation of the ret1-1 mutation in yeast, which reduces the efficiency of transcription termination by RNA polymerase III. We have cloned the RET1 gene by complementation of an ochre suppression phenotype in ret1-1 cells. The RET1 gene was mapped to near the HIS3 gene on the right arm of chromosome 15 by using hybridization to OFAGE gels. Sequencing of the RET1 gene has identified its product as the second-largest subunit of RNA polymerase III. We have carried out an extensive sequence alignment with other RNA polymerase second-largest subunits and discuss the conservation of several functional domains. The RET1 gene was used to recover the ret1-1 mutant allele from genomic DNA using an integration/excision technique. Plasmid-based fine mapping and fragment swapping were used to localize the ret1-1 mutation for sequencing. We discuss the ret1-1 sequence lesion with regard to possible roles in transcription. In particular, the recessive nature of the ret1-1 mutation may have major implications for our understanding of the transcription process.
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PMID:The RET1 gene of yeast encodes the second-largest subunit of RNA polymerase III. Structural analysis of the wild-type and ret1-1 mutant alleles. 200 1

We developed a procedure to measure mRNA decay rates in the yeast Saccharomyces cerevisiae and applied it to the determination of half-lives for 20 mRNAs encoded by well-characterized genes. The procedure utilizes Northern (RNA) or dot blotting to quantitate the levels of individual mRNAs after thermal inactivation of RNA polymerase II in an rpb1-1 temperature-sensitive mutant. We compared the results of this procedure with results obtained by two other procedures (approach to steady-state labeling and inhibition of transcription with Thiolutin) and also evaluated whether heat shock alter mRNA decay rates. We found that there are no significant differences in the mRNA decay rates measured in heat-shocked and non-heat-shocked cells and that, for most mRNAs, different procedures yield comparable relative decay rates. Of the 20 mRNAs studied, 11, including those encoded by HIS3, STE2, STE3, and MAT alpha 1, were unstable (t1/2 less than 7 min) and 4, including those encoded by ACT1 and PGK1, were stable (t1/2 greater than 25 min). We have begun to assess the basis and significance of such differences in the decay rates of these two classes of mRNA. Our results indicate that (i) stable and unstable mRNAs do not differ significantly in their poly(A) metabolism; (ii) deadenylation does not destabilize stable mRNAs; (iii) there is no correlation between mRNA decay rate and mRNA size; (iv) the degradation of both stable and unstable mRNAs depends on concomitant translational elongation; and (v) the percentage of rare codons present in most unstable mRNAs is significantly higher than in stable mRNAs.
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PMID:Identification and comparison of stable and unstable mRNAs in Saccharomyces cerevisiae. 218 28

The Saccharomyces cerevisiae gene encoding the smallest RNA polymerase II subunit, RPB10, was isolated and sequenced. The gene for this subunit is present in single copy and maps to chromosome XV, where two other yeast RNA polymerase II subunits, RPB2 and RPB8, reside. The RPB10 sequence predicts a protein only 46 amino acids in length with a molecular mass of 5400 daltons. Sporulation and tetrad analysis of diploid cells containing one copy of the RPB10 gene and one copy of HIS3 in place of the RPB10 gene revealed that the RPB10 subunit is essential for viability.
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PMID:RNA polymerase II subunit RPB10 is essential for yeast cell viability. 850 44

We have constructed a yeast strain (UKY403) in which the sole histone H4 gene is under control of the GAL1 promoter. This allows the activation of H4 mRNA synthesis on galactose and its repression on glucose. UKY403 cells, pre-synchronized in G1 with alpha-mating factor, have been used to show that glucose treatment results in the loss of approximately half the chromosomal nucleosomes. This depletion is only partially reversible when the H4 gene is reactivated on galactose. It was found that the resultant lethality manifests itself first in S phase, the period of nucleosome assembly, but leads to highly synchronous arrest in G2 and a virtually complete block in chromosomal segregation. Histone H4-depleted chromatin was analyzed for its efficiency as a template for all three RNA polymerases. Using pulse-labeling, we find no evidence for altered transcription by RNA polymerase I (25S, 18S and 5.8S rRNAs) or RNA polymerase III (5S rRNA, tRNAs). Northern blot analysis was used to measure levels of RNA polymerase II transcripts. There was little effect on the activation or repression of the CUP1 chelatin gene. While there may be some decrease in the level of certain mRNAs (e.g. HIS4, ARG4) other message levels (HIS3, TRP1) show little change upon glucose repression. Therefore, nucleosome loss certainly does not have a general effect on transcription.
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PMID:Effects of histone H4 depletion on the cell cycle and transcription of Saccharomyces cerevisiae. 304 33

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

The yeast imidazoleglycerolphosphate dehydratase gene HIS3, when introduced into Escherichia coli, is transcribed and translated with sufficient fidelity to produce functional enzyme. The following lines of evidence indicate that E. coli RNA polymerase recognizes a particular region of HIS3 DNA as a promoter sequence. First, this promoter contains nucleotide sequences that resemble the canonical prokaryotic promoter elements, the -10 and -35 regions. Second, HIS3 transcription in vitro by E. coli RNA polymerase is initiated at the predicted site downstream from the conserved sequences. Third, deletion mutations that successively encroach upon the 5' end of the HIS3 gene indicate that the promoter is necessary and sufficient for expression in E. coli. Fourth, a single base-pair change that behaves as an "up-promoter" mutation alters the -35 region such that it becomes identical with the consensus sequence. Because the -10 region of this promoter coincides with the TATA promoter element that is necessary for expression in yeast cells, it is possible directly to compare prokaryotic and eukaryotic promoter function. Analysis of 51 deletion and substitution mutations indicates that the patterns of mutant phenotypes are quite different for each organism. Therefore, although prokaryotic -10 regions are similar in sequence to eukaryotic TATA elements and although the same his3 region serves both functions, it appears that this represents an evolutionary coincidence whose current functional basis is minimal. The evolutionary significance of the homology between prokaryotic and eukaryotic promoter elements is discussed.
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PMID:Yeast HIS3 expression in Escherichia coli depends upon fortuitous homology between eukaryotic and prokaryotic promoter elements. 354 77

The yeast GCN4 gene product is necessary for the transcriptional induction of many amino acid biosynthetic genes in response to conditions of amino acid starvation. We synthesized radioactively pure GCN4 protein by in vitro translation of mRNA produced by in vitro transcription with SP6 RNA polymerase. GCN4 protein binds specifically to the 20 bp region of the HIS3 gene that is critical for transcriptional regulation in vivo and contains the TGACTC sequence common to coregulated genes. A synthetic GCN4 mutant protein lacking the 40 C-terminal amino acids fails to bind DNA; this correlates with a gcn4 mutant gene that is nonfunctional in vivo. Finally, GCN4 protein binds to the promoter regions of coordinately regulated genes, but not to analogous regions of other genes. We suggest that GCN4 protein is a specific transcription factor, and we describe a molecular model for the general control of amino acid biosynthetic genes.
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PMID:GCN4 protein, synthesized in vitro, binds HIS3 regulatory sequences: implications for general control of amino acid biosynthetic genes in yeast. 390 51

Four cDNAs encoding human polypeptides hRPB7.0, hRPB7.6, hRPB17, and hRPB14.4 (referred to as Hs10 alpha, Hs10 beta, Hs8, and Hs6, respectively), homologous to the ABC10 alpha, ABC10 beta, ABC14.5, and ABC23 RNA polymerase subunits (referred to as Sc10 alpha, Sc10 beta, Sc8, and Sc6, respectively) of Saccharomyces cerevisiae, were cloned and characterized for their ability to complement defective yeast mutants. Hs10 alpha and the corresponding Sp10 alpha of Schizosaccharomyces pombe can complement an S. cerevisiae mutant (rpc10-delta::HIS3) defective in Sc10 alpha. The peptide sequences are highly conserved in their carboxy-terminal halves, with an invariant motif CX2CX12RCX2CGXR corresponding to a canonical zinc-binding domain. Hs10 beta, Sc10 beta, and the N subunit of archaeal RNA polymerase are homologous. An invariant CX2CGXnCCR motif presumably forms an atypical zinc-binding domain. Hs10 beta, but not the archaeal subunit, complemented an S. cerevisiae mutant (rpb10-delta 1::HIS3) lacking Sc10 beta. Hs8 complemented a yeast mutant (rpb8-delta 1::LYS2) defective in the corresponding Sc8 subunit, although with a strong thermosensitive phenotype. Interspecific complementation also occurred with Hs6 and with the corresponding Dm6 cDNA of Drosophila melanogaster. Hs6 cDNA and the Sp6 cDNA of S. pombe are dosage-dependent suppressors of rpo21-4, a mutation generating a slowly growing yeast defective in the largest subunit of RNA polymerase II. Finally, a doubly chimeric S. cerevisiae strain bearing the Sp6 cDNA and the human Hs10 beta cDNA was also viable. No interspecific complementation was observed for the human hRPB25 (Hs5) homolog of the yeast ABC27 (Sc5) subunit.
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PMID:Four subunits that are shared by the three classes of RNA polymerase are functionally interchangeable between Homo sapiens and Saccharomyces cerevisiae. 765 87

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