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)

The ribosomal proteins (RPs) of Saccharomyces cerevisiae are encoded by 137 genes that are among the most transcriptionally active in the genome. These genes are coordinately regulated: a shift up in temperature leads to a rapid, but temporary, decline in RP mRNA levels. A defect in any part of the secretory pathway leads to greatly reduced ribosome synthesis, including the rapid loss of RP mRNA. Here we demonstrate that the loss of RP mRNA is due to the rapid transcriptional silencing of the RP genes, coupled to the naturally short lifetime of their transcripts. The data suggest further that a global inhibition of polymerase II transcription leads to overestimates of the stability of individual mRNAs. The transcription of most RP genes is activated by two Rap1p binding sites, 250 to 400 bp upstream from the initiation of transcription. Rap1p is both an activator and a silencer of transcription. The swapping of promoters between RPL30 and ACT1 or GAL1 demonstrated that the Rap1p binding sites of RPL30 are sufficient to silence the transcription of ACT1 in response to a defect in the secretory pathway. Sir3p and Sir4p, implicated in the Rap1p-mediated repression of silent mating type genes and of telomere-proximal genes, do not influence such silencing of RP genes. Sir2p, implicated in the silencing both of the silent mating type genes and of genes within the ribosomal DNA locus, does not influence the repression of either RP or rRNA genes. Surprisingly, the 180-bp sequence of RPL30 that lies between the Rap1p sites and the transcription initiation site is also sufficient to silence the Gal4p-driven transcription in response to a defect in the secretory pathway, by a mechanism that requires the silencing region of Rap1p. We conclude that for Rap1p to activate the transcription of an RP gene it must bind to upstream sequences; yet for Rap1p to repress the transcription of an RP gene it need not bind to the gene directly. Thus, the cell has evolved a two-pronged approach to effect the rapid extinction of RP synthesis in response to the stress imposed by a heat shock or by a failure of the secretory pathway. Calculations based on recent transcriptome data and on the half-life of the RP mRNAs suggest that in a rapidly growing cell the transcription of RP mRNAs accounts for nearly 50% of the total transcriptional events initiated by RNA polymerase II. Thus, the sudden silencing of the RP genes must have a dramatic effect on the overall transcriptional economy of the cell.
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PMID:Transcriptional elements involved in the repression of ribosomal protein synthesis. 1040 30

The SAGA complex of Saccharomyces cerevisiae is required for the transcription of many RNA polymerase II-dependent genes. Previous studies have demonstrated that SAGA possesses histone acetyltransferase activity, catalyzed by the SAGA component Gcn5. However, the transcription of many genes, although SAGA dependent, is Gcn5 independent, suggesting the existence of distinct SAGA activities. We have studied the in vivo role of two other SAGA components, Spt3 and Spt20, at the well-characterized GAL1 promoter. Our results demonstrate that both Spt3 and Spt20 are required for the binding of TATA-binding protein but not of the activator Gal4 and that this role is Gcn5 independent. These results suggest a coactivator role for Spt3 and Spt20 in the recruitment of TBP.
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PMID:The Spt components of SAGA facilitate TBP binding to a promoter at a post-activator-binding step in vivo. 1058 1

The general transcription factor TFIIH is required for initial DNA unwinding and promoter escape by RNA polymerase II in vitro. We examined whether Rad25p, a DNA helicase subunit of TFIIH, mediates promoter opening and promoter escape in the yeast Saccharomyces cerevisiae. DNA unwinding was probed with an in vivo permanganate reactivity assay, in a temperature-sensitive mutant of RAD25. The consequences of Rad25p inactivation were promoter-specific. Whereas in the TDH2 promoter permanganate reactivity was entirely abolished, the reactivity at the GAL1 and GAL10 promoter regions was only moderately affected. In the GAL genes permanganate reactivity uniformly decreased downstream of the transcription start site, indicating that progression of RNA polymerase II to this region was impaired. Our results suggest that in yeast cells, promoter opening is not sufficient for productive initiation and that Rad25p-mediated promoter escape may be a limiting step in the transcription of some promoters.
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PMID:Rad25p, a DNA helicase subunit of yeast transcription factor TFIIH, is required for promoter escape in vivo. 1071 51

The impact of high levels of RNA polymerase II transcription on mitotic recombination was examined using lys2 recombination substrates positioned on nonhomologous chromosomes. Substrates were used that could produce Lys(+) recombinants by either a simple (noncrossover) gene conversion event or a crossover-associated recombination event, by only a simple gene conversion event, or by only a crossover event. Transcription of the lys2 substrates was regulated by the highly inducible GAL1-10 promoter or the low-level LYS2 promoter, with GAL1-10 promoter activity being controlled by the presence or absence of the Gal80p negative regulatory protein. Transcription was found to stimulate recombination in all assays used, but the level of stimulation varied depending on whether only one or both substrates were highly transcribed. In addition, there was an asymmetry in the types of recombination events observed when one substrate versus the other was highly transcribed. Finally, the lys2 substrates were positioned as direct repeats on the same chromosome and were found to exhibit a different recombinational response to high levels of transcription from that exhibited by the repeats on nonhomologous chromosomes. The relevance of these results to the mechanisms of transcription-associated recombination are discussed.
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PMID:Stimulation of mitotic recombination events by high levels of RNA polymerase II transcription in yeast. 1089 81

The C-terminal heptad repeat domain (CTD) of RNA polymerase II (pol II) is proposed to target pre-mRNA processing enzymes to nascent pol II transcripts, but this idea has not been directly tested in vivo. In vitro, the yeast mRNA capping enzymes Ceg1 and Abd1 bind specifically to the phosphorylated CTD. Here we show that yeast capping enzymes cross-link in vivo to the 5' ends of transcribed genes and that this localization requires the CTD. Both the extent of CTD phosphorylation at Ser 5 of the heptad repeat and the binding of capping enzymes decreased as polymerase moved from the 5' to the 3' ends of the ACT1, ENO2, TEF1, GAL1, and GAL10 genes. Ceg1 is released early in elongation, but Abd1 can travel with transcribing pol II as far as the 3' end of a gene. The CTD kinase, Kin28, is required for binding, and the CTD phosphatase, Fcp1, is required for dissociation of capping enzymes from the elongation complex. CTD phosphorylation and dephosphorylation therefore control the association of capping enzymes with pol II as it transcribes a gene.
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PMID:Dynamic association of capping enzymes with transcribing RNA polymerase II. 1101 11

The mediator complex in the RNA polymerase II holoenzyme is known to be involved in transcriptional activation. The role of the essential mediator component Srb7p has been difficult to investigate, since no conditional lethal allele has been available to date. While the expression of Srb7p under the control of a repressible promoter is not sufficient to reduce the level of Srb7p beneath the threshold for survival, we have been able to isolate a clone termed ts16 which confers a temperature sensitive phenotype. ts16 contains an insertion mutation that requires translational frameshifting for correct expression of Srb7p, leading to extremely low protein levels. Strains bearing the ts16 construct show mild defects in the transcription of constitutive genes like TDH1 but severely affect activated transcription, e.g. of the GAL1 gene. In contrast, CUP1, which is also independent of other holoenzyme components, is not affected by ts16.
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PMID:Srb7p is essential for the activation of a subset of genes. 1105 20

In vitro, transcript elongation by RNA polymerase II is impeded by DNA sequences, DNA-bound proteins, and small ligands. Transcription elongation factor SII (TFIIS) assists RNA polymerase II to transcribe through these obstacles. There is however, little direct evidence that SII-responsive arrest sites function in living cells nor that SII facilitates readthrough in vivo. Saccharomyces cerevisiae strains lacking elongation factor SII and/or containing a point mutation in the second largest subunit of RNA polymerase II, which slows the enzyme's RNA elongation rate, grow slowly and have defects in mRNA metabolism, particularly in the presence of nucleotide-depleting drugs. Here we have examined transcriptional induction in strains lacking SII or containing the slow polymerase mutation. Both mutants and a combined double mutant were defective in induction of GAL1 and ENA1. This was not due to an increase in mRNA degradation and was independent of any drug treatment, although treatment with the nucleotide-depleting drug 6-azauracil exacerbated the effect preferentially in the mutants. These data are consistent with mutants in the Elongator complex, which show slow inductive responses. When a potent in vitro arrest site was transcribed in these strains, there was no perceptible effect upon mRNA accumulation. These data suggest that an alternative elongation surveillance mechanism exists in vivo to overcome arrest.
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PMID:Analysis of gene induction and arrest site transcription in yeast with mutations in the transcription elongation machinery. 1127 87

Evolutionarily conserved variant histone H2A.Z has been recently shown to regulate gene transcription in Saccharomyces cerevisiae. Here we show that loss of H2A.Z in this organism negatively affects the induction of GAL genes. Importantly, fusion of the H2A.Z C-terminal region to S phase H2A without its corresponding C-terminal region can mediate the variant histone's specialized function in GAL1-10 gene induction, and it restores the slow-growth phenotype of cells with a deletion of HTZ1. Furthermore, we show that the C-terminal region of H2A.Z can interact with some components of the transcriptional apparatus. In cells lacking H2A.Z, recruitment of RNA polymerase II and TATA-binding protein to the GAL1-10 promoters is significantly diminished under inducing conditions. Unexpectedly, we also find that H2A.Z is required to globally maintain chromatin integrity under GAL gene-inducing conditions. We hypothesize that H2A.Z can positively regulate gene transcription, at least in part, by modulating interactions with RNA polymerase II-associated factors at certain genes under specific cell growth conditions.
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PMID:H2A.Z is required for global chromatin integrity and for recruitment of RNA polymerase II under specific conditions. 1150 69

The 19S proteasome regulatory particle plays a critical role in cellular proteolysis. However, recent reports have demonstrated that 19S proteins play a nonproteolytic role in nucleotide excision repair and transcription elongation. We show by chromatin immunoprecipitation assays that proteins comprising the 19S complex are recruited to the GAL1-10 promoter by the Gal4 transactivator upon induction with galactose. This recruited complex does not contain proteins from the 20S proteolytic particle and includes a subset of the 19S proteins. This subset is also specifically retained from an extract by the Gal4 activation domain. These data indicate that in vivo, the base of the 19S complex functions independently of the larger complex and plays a direct, nonproteolytic role in RNA polymerase II transcription.
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PMID:Recruitment of a 19S proteasome subcomplex to an activated promoter. 1196 65

Transcription-coupled repair (TCR) and global genomic repair (GGR) of UV-induced cyclobutane pyrimidine dimers were investigated in the yeast GAL1-10 genes. Both Rpb9- and Rad26-mediated TCR are confined to the transcribed strands, initiating at upstream sites approximately 100 nucleotides from the upstream activating sequence shared by the two genes. However, TCR initiation sites do not correlate with either transcription start sites or TATA boxes. Rad16-mediated GGR tightly correlates with nucleosome positioning when the genes are repressed and are slow in the nucleosome core and fast in linker DNA. Induction of transcription enhanced GGR in nucleosome core DNA, especially in the nucleosomes around and upstream of the transcription start sites. Furthermore, when the genes were induced, GGR was slower in the transcribed regions than in the upstream regions. Finally, simultaneous deletion of RAD16, RAD26, and RPB9 resulted in no detectable repair in all sites along the region analyzed. Our results suggest that (a). TCR may be initiated by a transcription activator, presumably through the loading of RNA polymerase II, rather than by transcription initiation or elongation per se; (b). TCR and nucleosome disruption-enhanced GGR are the major causes of rapid repair in regions around and upstream of transcription start sites; (c). transcription machinery may hinder access of NER factors to a DNA lesion in the absence of a transcription-repair coupling factor; and (d). other than GGR mediated by Rad16 and TCR mediated by Rad26 and Rpb9, no other nucleotide excision repair pathway exists in these RNA polymerase II-transcribed genes.
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PMID:Dissecting transcription-coupled and global genomic repair in the chromatin of yeast GAL1-10 genes. 1473 64

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