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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)

Two ribonuclease H activities have been found in yeast RNA polymerase A. The nuclease activities comigrated with subunits A49 (Mr = 49,000) and A40 (Mr = 40,000), after electrophoresis in a sodium dodecyl sulfate polyacrylamide gel containing [32P](rG)n . (dC)n as substrate. Both activities were also found, among other nucleases, in a high salt chromatin extract. Several lines of evidence suggest that the chromatin RNase H of 49,000 daltons (RNase H49) is the same protein as subunit A49. They co-migrate on sodium dodecyl sulfate-gel electrophoresis, have the same chromatographic properties, and dissociate simultaneously from RNA polymerase A. Fractions containing RNase H49 stimulate RNA synthesis by RNA polymerase A* lacking A49 and A34.5 subunits. Finally, limited proteolysis of the protein band having RNase H49 activity yields the characteristic fingerprint of the A49 subunit. This subunit, therefore, exists in two states: bound to chromatin and associated with RNA polymerase A. On the other hand, it is not yet clear whether the RNase H activity of 40,000 daltons, associated with RNA polymerase A, is due to the A40 subunit or whether it represents a trace contamination by a very active nuclease tightly bound to the enzyme.
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PMID:Identification of two different RNase H activities associated with yeast RNA polymerase A. 38 60

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

Monoclonal antibodies were raised in mouse against native RNA polymerase A from Saccharomyces cerevisiae. After screening with the spot-immunodetection technique, 14 hybridomas were selected and the antibodies produced in mice. Their specificity, analyzed by blot-immunodetection, was found to be markedly biased towards a few RNA polymerase subunits: A135 , A49 , A43 , and A14.5. A different monoclonal antibody directed against the largest subunit, A190 , was obtained by immunizing a mouse with RNA polymerase A dissociated into its subunits with SDS. Two antibodies, which probably recognized the same antigenic determinant on subunit A135 , inhibited in vitro RNA synthesis. Inhibition was prevented by preincubation of the enzyme with DNA, suggesting a role for the A135 subunit in template binding. The antibody directed against A14.5 interacted with the A14.5 kd subunit present in all three forms of the yeast nuclear RNA polymerases but did not interfere with RNA polymerase activity. These antibody probes will be useful to study subunit function in reconstituted transcription systems.
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PMID:Probing yeast RNA polymerase A subunits with monospecific antibodies. 620 6

There is a natural variation in the molecular structure of RNA polymerase A isolated from several genetically distant yeast species, Saccharomyces cerevisiae, Saccharomyces douglasii, Schizosaccharomyces pombe, and Candida tropicalis. Several biochemical criteria were used to identify their homologous polypeptide components. Based on these correlations, the minimal subunit composition of S. cerevisiae (and Saccharomyces carlsbergensis) RNA polymerase A was tentatively defined as A190, A135, A40, A27, A23, A19, and A14.5. Without the two Saccharomyces species, S. cerevisiae and S. douglasii, 7 of 13 polypeptides of enzyme A(A49, A43, A40, A34.5, A19, A14.5, and A14) differ slightly in molecular weight and can be resolved by electrophoresis on polyacrylamide gel. The RNA polymerase A isolated from the diploid interspecific hybrid contains all the polypeptides characteristic of the two parents. One meiotic segregant had a hybrid RNA polymerase A with five of the polymorphic polypeptides (A49, A43, A19, A14.5, and A14) coming from S. douglasii and two (A40 and A34.5) from S. cerevisiae. In three successive backcrosses with S. cerevisiae, all the genes for S. douglasii polypeptides were shown to recombine although parental ditype tetrads predominated in the four four-spored asci examined. Thus, the genes for the seven polymorphic polypeptides are not clustered: they lie on at least three different chromosomes.
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PMID:Natural variation in yeast RNA polymerase A. Formation of a mosaic RNA polymerase A in a meiotic segregant from an interspecific hybrid. 704 Mar 85

Mouse RNA polymerase I (Pol I) has, besides its 11 bona fide subunits, three polymerase associated factors, termed PAF53, 51 and 49 with respect to the size of each molecule. In order to analyze the function of PAFs, cDNA encoding PAF53 was isolated using an oligonucleotide probe derived from an oligopeptide sequence. The cDNA of PAF53 predicts a polypeptide of 434 amino acids with a sequence similarity to yeast Pol 1 49 kDa subunit. Anti-PAF53 antibody does not block the random transcription activity of Pol I, but blocks specific transcription from mouse ribosomal RNA promoter, demonstrating the requirement of PAF53 in the accurate initiation of Pol I transcription. Moreover, PAF53 interacted with mouse UBF in vitro, as revealed by Far-Western blotting and GST pull down assays. These results, together with the accumulation of PAF53 in the nucleolus of growing cells, suggest that PAF53 is involved in the formation of the initiation complex at the promoter by mediating the interaction between Pol I and UBF for the active rRNA synthesis.
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PMID:RNA polymerase I associated factor 53 binds to the nucleolar transcription factor UBF and functions in specific rDNA transcription. 864 Dec 87

A34.5, a phosphoprotein copurifying with RNA polymerase I (Pol I), lacks homology to any component of the Pol II or Pol III transcription complexes. Cells devoid of A34.5 hardly affect growth and rRNA synthesis and generate a catalytically active but structurally modified enzyme also lacking subunit A49 upon in vitro purification. Other Pol I-specific subunits (A49, A14, and A12.2) are nonessential for growth at 30 degrees C but are essential (A49 and A12.2) or helpful (A14) at 25 or 37 degrees C. Triple mutants without A34.5, A49, and A12.2 are viable, but inactivating any of these subunits together with A14 is lethal. Lethality is rescued by expressing pre-rRNA from a Pol II-specific promoter, demonstrating that these subunits are collectively essential but individually dispensable for rRNA synthesis. A14 and A34.5 single deletions affect the subunit composition of the purified enzyme in pleiotropic but nonoverlapping ways which, if accumulated in the double mutants, provide a structural explanation for their strict synthetic lethality. A34.5 (but not A14) becomes quasi-essential in strains lacking DNA topoisomerase I, suggesting a specific role of this subunit in helping Pol I to overcome the topological constraints imposed on ribosomal DNA by transcription.
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PMID:A34.5, a nonessential component of yeast RNA polymerase I, cooperates with subunit A14 and DNA topoisomerase I to produce a functional rRNA synthesis machine. 912 26

Mouse RNA polymerase I (Pol I) is composed of 14 polypeptides, 3 of which are thought to be loosely associated with, and may be dislodged from, Pol I. To find out whether these polymerase-associated factors (PAF53, 51, and 49) serve a role in growth-dependent control of rDNA transcription, we generated polyclonal antibodies against three subunits of murine Pol I, RPA116, RPA40 and PAF53, and used different experimental approaches, e.g. immunoblot analysis, immunoprecipitation and immunofluorescence studies, to compare the stoichiometry of individual subunits both in different Pol I preparations and in extracts from cells grown under different conditions. This comparative analysis reveals that the molar ratio of the second largest subunit RPA116 to PAF53 is the same, irrespective of whether crude extracts or highly purified Pol I fractions are analyzed. Significantly, the relative level of PAF53 was comparable in exponentially growing or growth-arrested cells, indicating that growth-dependent fluctuations in Pol I activity are not accompanied by alterations in the amount of PAF53. In addition, we show by high resolution immunofluorescence analysis that, under conditions of repressed rDNA transcription, including serum starvation, actinomycin treatment und during mitosis, PAF53 remains attached to the transcriptional machinery. The finding that the Mr 53,000 protein remains in the multiprotein complex under all experimental conditions tested indicates that PAF53 is not a loosely associated regulatory factor but a bona fide subunit of Pol I.
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PMID:Constitutive and strong association of PAF53 with RNA polymerase I. 925 23

The experiments reported here used 3T6-Swiss albino mouse fibroblasts and H4-II-E-C3 rat hepatoma cells as model systems to examine the mechanism(s) through which insulin regulates rDNA transcription. Serum starvation of 3T6 cells for 72 h resulted in a marked reduction in rDNA transcription. Treatment of serum-deprived cells with insulin was sufficient to restore rDNA transcription to control values. In addition, treatment of exponentially growing H4-II-E-C3 with insulin stimulated rDNA transcription. However, for both cell types, the stimulation of rDNA transcription in response to insulin was not associated with a change in the cellular content of RNA polymerase I. Thus we conclude that insulin must cause alterations in formation of the active RNA polymerase I initiation complex and/or the activities of auxiliary rDNA transcription factors. In support of this conclusion, insulin treatment of both cell types was found to increase the nuclear content of upstream binding factor (UBF) and RNA polymerase I-associated factor 53. Both of these factors are thought to be involved in recruitment of RNA polymerase I to the rDNA promoter. Nuclear run-on experiments demonstrated that the increase in cellular content of UBF was due to elevated transcription of the UBF gene. In addition, overexpression of UBF was sufficient to directly stimulate rDNA transcription from a reporter construct. The results demonstrate that insulin is capable of stimulating rDNA transcription in both 3T6 and H4-II-E-C3 cells, at least in part by increasing the cellular content of components required for assembly of RNA polymerase I into an active complex.
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PMID:Regulation of ribosomal DNA transcription by insulin. 968 43

In mammalian preovulatory oocytes, rRNA synthesis is down-regulated until egg fertilization and zygotic genome reactivation, but the underlying regulatory mechanisms of this phenomenon are poorly characterized. We examined the molecular organization of the rRNA synthesis and processing machineries in fully grown mouse oocytes in relation to ongoing rDNA transcription and oocyte progression throughout meiosis. We show that, at the germinal vesicle stage, the two RNA polymerase I (RNA pol I) subunits, RPA116 and PAF53/RPA53, and the nucleolar upstream binding factor (UBF) remain present irrespective of ongoing rDNA transcription and colocalize in stoichiometric amounts within discrete foci at the periphery of the nucleolus-like bodies. These foci are spatially associated with the early pre-rRNA processing protein fibrillarin and in part with the pre-ribosome assembly factor B23/nucleophosmin. After germinal vesicle breakdown, the RNA pol I complex disassembles in a step-wise manner from chromosomes, while UBF remains associated with chromosomes until late prometaphase I. Dislodging of UBF, but not of RNA pol I, is impaired by the phosphatase inhibitor okadaic acid, thus strengthening the idea of a relationship between UBF dynamics and protein phosphorylation. Since neither RNA pol I, UBF, fibrillarin, nor B23 is detected at metaphase II, i.e., the normal stage of fertilization, we conclude that these nucleolar proteins are not transported to fertilized eggs by maternal chromosomes. Together, these data demonstrate an essential difference in the dynamics of the major nucleolar proteins during mitosis and meiosis.
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PMID:Functional and molecular reorganization of the nucleolar apparatus in maturing mouse oocytes. 1088 21

When 3T6 cells are confluent, they withdraw from the cell cycle. Concomitant with cell cycle arrest a significant reduction in RNA polymerase I transcription (80% decrease at 100% confluence) is observed. In the present study, we examined mechanism(s) through which transcription of the ribosomal genes is coupled to cell cycle arrest induced by cell density. Interestingly with an increase in cell density (from 3 - 43% confluence), a significant accumulation in the cellular content of hyperphosphorylated Rb was observed. As cell density increased further, the hypophosphorylated form of Rb became predominant and accumulated in the nucleoli. Co-immunoprecipitation experiments demonstrated there was also a significant rise in the amount of hypophosphorylated Rb associated with the rDNA transcription factor UBF. This increased interaction between Rb and UBF correlated with the reduced rate of rDNA transcription. Furthermore, overexpression of recombinant Rb inhibited UBF-dependent activation of transcription from a cotransfected rDNA reporter in either confluent or exponential cells. The amounts or activities of the rDNA transcription components we examined did not significantly change with cell cycle arrest. Although the content of PAF53, a polymerase associated factor, was altered marginally (decreased 38%), the time course and magnitude of the decrease did not correlate with the reduced rate of rDNA transcription. The results presented support a model wherein regulation of the binding of UBF to Rb and, perhaps the cellular content of PAF53, are components of the mechanism through which cell cycle and rDNA transcription are linked. Oncogene (2000) 19, 3487 - 3497
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PMID:RNA polymerase I transcription in confluent cells: Rb downregulates rDNA transcription during confluence-induced cell cycle arrest. 1091 7

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