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)

Both the gene and the cDNA encoding the Rpb4 subunit of RNA polymerase II were cloned from the fission yeast Schizosaccharomyces pombe. The cDNA sequence indicates that Rpb4 consists of 135 amino acid residues with a molecular weight of 15,362. As in the case of the corresponding subunits from higher eukaryotes such as humans and the plant Arabidopsis thaliana, Rpb4 is smaller than RPB4 from the budding yeast Saccharomyces cerevisiae and lacks several segments, which are present in the S. cerevisiae RPB4 subunit, including the highly charged sequence in the central portion. The RPB4 subunit of S. cerevisiae is not essential for normal cell growth but is required for cell viability under stress conditions. In contrast, S. pombe Rpb4 was found to be essential even under normal growth conditions. The fraction of RNA polymerase II containing RPB4 in exponentially growing cells of S. cerevisiae is about 20%, but S. pombe RNA polymerase II contains the stoichiometric amount of Rpb4 even at the exponential growth phase. In contrast to the RPB4 homologues from higher eukaryotes, however, S. pombe Rpb4 formed stable hybrid heterodimers with S. cerevisiae RPB7, suggesting that S. pombe Rpb4 is similar, in its structure and essential role in cell viability, to the corresponding subunits from higher eukaryotes. However, S. pombe Rpb4 is closer in certain molecular functions to S. cerevisiae RPB4 than the eukaryotic RPB4 homologues.
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PMID:The Rpb4 subunit of fission yeast Schizosaccharomyces pombe RNA polymerase II is essential for cell viability and similar in structure to the corresponding subunits of higher eukaryotes. 1052 39

As an approach to elucidating the rules governing the assembly of human RNA polymerase II (hRPB), interactions between its subunits have been systematically analyzed. Eleven of the 12 expected hRPB subunits have previously been tested for reciprocal interactions (J. Biol. Chem. 272 (1997) 16815-16821). We now report the results obtained for the last subunit (hRPB4; Mol. Cell. Biol. 18 (1998) 1935-1945) and propose an essentially complete picture of the potential interactions occurring within hRPB. Finally, complementation experiments in yeast indicated that hRPB4 expression efficiently cured both heat and cold-sensitivity of RPB4-lacking strains, supporting the existence of conserved functional subunit interactions.
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PMID:Interactions between the full complement of human RNA polymerase II subunits. 1056 6

The archaeal and eukaryotic evolutionary domains diverged from each other approximately 2 billion years ago, but many of the core components of their transcriptional and translational machineries still display a readily recognizable degree of similarity in their primary structures. The F and P subunits present in archaeal RNA polymerases were only recently identified in a purified archaeal RNA polymerase preparation and, on the basis of localized sequence homologies, tentatively identified as archaeal versions of the eukaryotic RPB4 and RPB12 RNA polymerase subunits, respectively. We prepared recombinant versions of the F and P subunits from Methanococcus jannaschii and used them in in vitro and in vivo protein interaction assays to demonstrate that they interact with other archaeal subunits in a manner predicted from their eukaryotic counterparts. The overall structural conservation of the M. jannaschii F subunit, although not readily recognizable on the primary amino acid sequence level, is sufficiently high to allow the formation of an archaeal-human F-RPB7 hybrid complex.
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PMID:Archaeal RNA polymerase subunits F and P are bona fide homologs of eukaryotic RPB4 and RPB12. 1105 30

The subunits of Saccharomyces cerevisiae RNA polymerase II (RNAP II) in proximity to the DNA during transcription elongation have been identified by photoaffinity cross-linking. In the absence of transcription factors, RNAP II will transcribe a double-stranded DNA fragment containing a 3'-extension of deoxycytidines, a "tailed template". We designed a DNA template allowing the RNAP to transcribe 76 bases before it was stalled by omission of CTP in the transcription reaction. This stall site oriented the RNAP on the DNA template and allowed us to map the RNAP subunits along the DNA. The DNA analogue 5-[N-(p-azidobenzoyl)-3-aminoallyl]-dUTP (N(3)RdUTP) [Bartholomew, B., Kassavetis, G. A., Braun, B. R., and Geiduschek, E. P. (1990) EMBO J. 9, 2197-205] was synthesized and enzymatically incorporated into the DNA at specified positions upstream or downstream of the stall site, in either the template or nontemplate strand of the DNA. Radioactive nucleotides were positioned beside the photoactivatable nucleotides, and cross-linking by brief ultraviolet irradiation transferred the radioactive tag from the DNA onto the RNAP subunits. In addition to N(3)RdUTP, which has a photoreactive azido group 9 A from the uridine base, we used the photoaffinity cross-linker 5N(3)dUTP with an azido group directly on the uridine ring to identify the RNAP II subunits closest to the DNA at positions where multiple subunits cross-linked. In cross-linking reactions dependent on transcription, RPB1, RPB2, and RPB5 were cross-linked with N(3)RdUTP. With 5N(3)dUTP, only RPB1 and RPB2 were cross-linked. Under certain circumstances, RPB3, RPB4, and RPB7 were cross-linked. From the information obtained in this topological study, we developed a model of yeast RNAP II in a transcription elongation complex.
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PMID:Topology of yeast RNA polymerase II subunits in transcription elongation complexes studied by photoaffinity cross-linking. 1106 78

We previously described the isolation of yeast mutants (sex mutants) that secrete reduced amounts of mature alpha-factor when it is synthesized as part of a fusion with prosomatostatin. In the present study we show that the sex3-1 mutant displays pleiotropic phenotypes. These include an abnormal morphology, an osmoremediable caffeine sensitivity, reduced secretion of mature alpha-factor, a weakened cell wall and a marked deficiency in halotolerance. Cloning of the SEX3 gene revealed that it is identical to the RPB4 gene. This gene encodes the fourth largest subunit of yeast RNA polymerase II, which has been postulated to play a major role in the response to stress. We show that transcriptional activation in response to either a cell wall stress or to growth in the presence of elevated salt concentrations is minimally affected by the loss of RPB4 function. However, whereas the levels of several mRNAs are similarly reduced (by about 30%) in rpb4 mutants grown in rich medium at moderate temperature, some transcripts, in particular ZDS1, are more abundant. An increase dosage of ZDS1, or of genes involved in cell wall assembly and in secretion (RHO1 and SR077, respectively), partially suppresses the sensitivity of rpb4delta cells to high temperature, heat shock and stationary phase. Collectively, our results indicate that the loss of Rpb4p perturbs several cellular functions that contribute to the inappropriate stress response of rpb4delta yeast. We therefore conclude that this RNA poiymerase II subunit is not specifically involved in the stress response.
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PMID:Multiple cellular processes affected by the absence of the Rpb4 subunit of RNA polymerase II contribute to the deficiency in the stress response of the yeast rpb4(delta) mutant. 1125 23

A major role in the regulation of eukaryotic protein-coding genes is played by the gene-specific transcriptional regulators, which recruit the RNA polymerase II holoenzyme to the specific promoter. Several components of the mediator complex within the holoenzyme also have been shown to affect activation of different subsets of genes. Only recently has it been suggested that besides the largest subunit of RNA polymerase II, smaller subunits like Rpb3 and Rpb5 may have regulatory roles in expression of specific sets of genes. We report here, the role of Rpb4, a non-essential subunit of core RNA polymerase II, in activation of a subset of genes in Saccharomyces cerevisiae. We have shown below that whereas constitutive transcription is largely unaffected, activation from various promoters tested is severely compromised in the absence of RPB4. This activation defect can be rescued by the overexpression of cognate activators. We have localized the region of Rpb4 involved in activation to the C-terminal 24 amino acids. We have also shown here that transcriptional activation by artificial recruitment of the TATA-binding protein (TBP) to the promoter is also defective in the absence of RPB4. Surprisingly, the overexpression of RPB7 (the interacting partner of Rpb4) does not rescue the activation defect of all the promoters tested, although it rescues the activation defect of the heat shock element-containing promoter and the temperature sensitivity associated with RPB4 deletion. Overall, our results indicate that Rpb4 and Rpb7 play independent roles in transcriptional regulation of genes.
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PMID:Rpb4, a non-essential subunit of core RNA polymerase II of Saccharomyces cerevisiae is important for activated transcription of a subset of genes. 1138 49

We used whole genome expression analysis to investigate the changes in the mRNA profile in cells lacking the Saccharomyces cerevisiae RNA polymerase II subunit RPB4 (Delta RPB4). Our results indicated that an essentially complete shutdown of transcription occurs upon temperature shift of this conditionally lethal mutant; 98% of mRNA transcript levels decrease at least 2-fold, 96% at least 4-fold. This data was supported by in vivo experiments that revealed a rapid and greater than 5-fold decline in steady state poly(A) RNA levels after the temperature shift. Expression of several individual genes, measured by Northern analysis, was also consistent with the whole genome expression profile. Finally we demonstrated that the loss of RNA polymerase II activity causes secondary effects on RNA polymerase I, but not RNA polymerase III, transcription. The transcription phenotype of the Delta RPB4 mutant closely mirrors that of the temperature-sensitive rpb1-1 mutant frequently implemented as a tool to inactivate the RNA polymerase II in vivo. Therefore, the Delta RPB4 mutant can be used to easily design strains that enable the study of distinct post-transcriptional cellular processes in the absence of RNA polymerase II transcription.
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PMID:Deletion of the RNA polymerase subunit RPB4 acts as a global, not stress-specific, shut-off switch for RNA polymerase II transcription at high temperatures. 1157 1

The eukaryotic subunits RPB4 and RPB7 form a heterodimer that reversibly associates with the RNA polymerase II core and constitute the only two components of the enzyme for which no structural information is available. We have determined the crystal structure of the complex between the Methanococcus jannaschii subunits E and F, the archaeal homologs of RPB7 and RPB4. Subunit E has an elongated two-domain structure and contains two potential RNA binding motifs, while the smaller F subunit wraps around one side of subunit E, at the interface between the two domains. We propose a model for the interaction between RPB4/RPB7 and the core RNA polymerase in which the RNA binding face of RPB7 is positioned to interact with the nascent RNA transcript.
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PMID:Structure of an archaeal homolog of the eukaryotic RNA polymerase II RPB4/RPB7 complex. 1174 48

Unlike Saccharomyces cerevisiae RNA polymerase III, human RNA polymerase III has not been entirely characterized. Orthologues of the yeast RNA polymerase III subunits C128 and C37 remain unidentified, and for many of the other subunits, the available information is limited to database sequences with various degrees of similarity to the yeast subunits. We have purified an RNA polymerase III complex and identified its components. We found that two RNA polymerase III subunits, referred to as RPC8 and RPC9, displayed sequence similarity to the RNA polymerase II RPB7 and RPB4 subunits, respectively. RPC8 and RPC9 associated with each other, paralleling the association of the RNA polymerase II subunits, and were thus paralogues of RPB7 and RPB4. Furthermore, the complex contained a prominent 80-kDa polypeptide, which we called RPC5 and which corresponded to the human orthologue of the yeast C37 subunit despite limited sequence similarity. RPC5 associated with RPC53, the human orthologue of S. cerevisiae C53, paralleling the association of the S. cerevisiae C37 and C53 subunits, and was required for transcription from the type 2 VAI and type 3 human U6 promoters. Our results provide a characterization of human RNA polymerase III and show that the RPC5 subunit is essential for transcription.
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PMID:Characterization of human RNA polymerase III identifies orthologues for Saccharomyces cerevisiae RNA polymerase III subunits. 1239 Nov 70

Organisms respond to environmental stress by adopting changes in gene expression at the transcriptional level. Rpb4, a nonessential subunit of the core RNA polymerase II has been proposed to play a role in non-stress-specific transcription and in the regulation of stress response in yeast. We find that in addition to the temperature sensitivity of the null mutant of Rpb4, diploid null mutants are also compromised in sporulation and show morphological changes associated with nitrogen starvation. Using whole genome expression analysis, we report here the effects of Rpb4 on expression of genes during normal growth and following heat shock and nutritional starvation. Our analysis shows that Rpb4 affects expression of a small yet significant fraction of the genome in both stress and normal conditions. We found that genes involved in galactose metabolism were dependent on the presence of Rpb4 irrespective of the environmental condition. Rpb4 was also found to affect the expression of several other genes specifically in conditions of nutritional starvation. The general defect in the absence of Rpb4 is in the expression of metabolic genes, especially those involved in carbon metabolism and energy generation. We report that various stresses are affected by RPB4 and that on overexpression the stress-specific activators can partially rescue the corresponding defects.
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PMID:Whole genome expression profiles of yeast RNA polymerase II core subunit, Rpb4, in stress and nonstress conditions. 1242 47

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