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 spoIIG promoter is used by RNA polymerase containing sigma A (E sigma A), the primary form of RNA polymerase found in vegetative cells in Bacillus subtilis. However, the spoIIG promoter is active only after the onset of sporulation. Activation of the spoIIG promoter requires the product of the spo0A gene (Spo0A). Spo0A is a sequence-specific DNA-binding protein which binds to two sites in the spoIIG promoter that are essential for promoter activity. We found that single-base-pair substitutions in these two regions that reduced promoter activity in vivo caused reduced binding of Spo0A in vitro, and one substitution that increased promoter activity in vivo increased the affinity of Spo0A for this DNA in vitro. Furthermore, Spo0A stimulated transcription from the spoIIG promoter by E sigma A in vitro. These results support the model that binding of Spo0A activates E sigma A-dependent transcription from the spoIIG promoter after the onset of sporulation.
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PMID:Binding of Spo0A stimulates spoIIG promoter activity in Bacillus subtilis. 153 90

Transcriptional regulation of the bacteriophage T4 late genes requires the participation of three DNA polymerase accessory proteins that are encoded by T4 genes 44, 62, and 45, and that act at an enhancer-like site. Transcriptional activation by these DNA replication proteins also requires the function of an RNA polymerase-bound coactivator protein that is encoded by T4 gene 33 and a promoter recognition protein that is encoded by T4 gene 55. Transcriptional activation in DNA constructs, in which the enhancer and a T4 late promoter can be segregated on two rings of a DNA catenane, has now been analyzed. The ability of an interposed DNA-binding protein to affect communication between the enhancer and the promoter was also examined. Together, these experiments demonstrate that this transcription-activating signal is conveyed between its enhancer and a T4 late promoter by a DNA-tracking mechanism. Alternative activation mechanisms relying entirely on through-space interactions of enhancer-bound and promoter-bound proteins are excluded.
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PMID:A transcriptional enhancer whose function imposes a requirement that proteins track along DNA. 159 72

The sigma 70 subunit of E. coli RNA polymerase is required for sequence-specific recognition of promoter DNA. Genetic studies and sequence analysis have indicated that sigma 70 contains two specific DNA-binding domains that recognize the two conserved portions of the prokaryotic promoter. However, intact sigma 70 does not bind to DNA. Using C-terminal and internal polypeptides of sigma 70, carrying one or both putative DNA-binding domains, we demonstrate that sigma 70 does contain two DNA-binding domains, but that N-terminal sequences inhibit the ability of intact sigma 70 to bind to DNA. Thus, we propose that sigma 70 is a sequence-specific DNA-binding protein that normally functions through an allosteric interaction with the core subunits of RNA polymerase.
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PMID:Polypeptides containing highly conserved regions of transcription initiation factor sigma 70 exhibit specificity of binding to promoter DNA. 164 61

Consistent with the complexity of the temporally regulated processes that must occur for growth and development of higher eukaryotes, it is now apparent that transcription is regulated by the formation of multicomponent complexes that assemble on the promoters of genes. These complexes can include (in addition to the five or more general transcription factors and RNA polymerase II) DNA-binding proteins, transcriptional activators, coactivators, adaptors and various accessory proteins. The best studied example of a complex that includes a transcriptional adaptor, accessory proteins and a DNA-binding protein is that involving the herpes simplex virus VP16 protein. Evidence suggests that the adenovirus E1a protein and the cellular Sp1 and CTF/NF1 transcription factors also function through adaptors or coactivators. Each additional component of the transcription complex provides the cell with another point at which to exert control of gene expression.
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PMID:The interactions of transcription factors and their adaptors, coactivators and accessory proteins. 166 80

Negative controls play an important role in the regulation of differentiation in many organisms. Sporulation in Bacillus subtilis is also regulated by DNA-binding proteins which exert a repressive effect on genes which are essential for this process. AbrB represses spo0H, coding for sigma H. One of the earliest events in the initiation of sporulation is the lifting of this repression so that more sigma H can be made. As part of an RNA polymerase holoenzyme, this positive transcription factor is responsible for the elevated synthesis of sufficient phosphorylated Spo0A to activate the expression of several stage II genes. Sin, another DNA-binding protein, represses the same genes, spoIIA, spoIIE and spoIIG, that are activated by Spo0A. Thus sporulation is controlled at the two earliest stages by at least two repressors. Sin and AbrB are repressors of other late growth functions but are essential for competence development. Sin is also a positive regulator for motility and autolysin production. These results suggest that AbrB and Sin act as developmental switches, enabling cells at the beginning of stationary growth to choose different developmental fates.
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PMID:The role of negative control in sporulation. 166 36

Two RNA polymerase sigma factors, sigma F and sigma E, are produced during the first two hours of endospore formation in Bacillus subtilis. Transcription of the structural genes for these factors is activated about one hour after the start of endospore formation. The operon encoding sigma F is transcribed by RNA polymerase containing sigma H, another secondary sigma factor, whereas the operon encoding sigma E is transcribed by RNA polymerase containing sigma A, the primary sigma factor in growing cells. Evidently, the coordinate temporal control of these transcriptional units is mediated by a factor other than the sigma factors, possibly by the DNA-binding protein encoded by spo0A. Both sigma F and sigma E activities are also regulated by mechanisms operating after transcription.
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PMID:Expression of stage II genes during sporulation in Bacillus subtilis. 178 21

The UL9 gene of herpes simplex virus (HSV) codes for a DNA-binding protein (OBP) that interacts sequence specifically with the origin of replication. This protein is essential for HSV DNA replication in cultured cells. The UL9 gene was cloned into a plasmid vector downstream of the SP6 RNA polymerase promoter. By using in vitro transcription and translation systems, a full-length OBP was synthesized. This synthetic protein is recognized by an antiserum generated against the C-terminal decapeptide of OBP and is functionally active in binding to OriS sequence specifically. The in vitro-synthesized protein has sequence specificity for binding similar to that found for the in vivo-generated OBP. A total of 14 in-frame deletion and insertion mutants of the UL9 gene were generated and expressed in vitro. Using these deletion mutants, we determined that the 269-amino-acid stretch defined by amino acids 564 to 832 localizes the OriS-specific DNA-binding domain. The N-terminal boundary is between amino acids 565 and 596, while the C terminus lies between amino acids 833 and 805. This segment contains a helix-turn-helix moiety and a pseudo-leucine zipper, neither of which alone can support DNA binding. The other leucine zipper from amino acids 150 to 173 is not required for the in vitro sequence-specific DNA-binding activity of OBP.
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PMID:A 269-amino-acid segment with a pseudo-leucine zipper and a helix-turn-helix motif codes for the sequence-specific DNA-binding domain of herpes simplex virus type 1 origin-binding protein. 185 56

Transcription factor IIIA (TFIIIA), a sequence-specific DNA-binding protein from Xenopus laevis, is a zinc finger protein required for transcription of 5S rRNA genes by RNA polymerase III. We describe the purification and characterization of recombinant TFIIIA (recTFIIIA) expressed in E. coli. RecTFIIIA was purified to greater than 95% homogeneity at a yield of 2-3 milligrams per liter of bacterial culture. This purified protein protects the internal control region of a 5S rRNA gene from DNase I digestion, yielding footprints on both strands identical to those produced by the ovarian protein (ovaTFIIIA). Quantitative analysis of binding data from gel retardation assays yielded a KD of about 0.4 nM for TFIIIA from either source. Using a quantitative TFIIIA-dependent in vitro transcription assay, we found that recTFIIIA is equivalent to ovaTFIIIA in supporting transcription of 5S rRNA genes. We conclude that recTFIIIA is functionally indistinguishable from the protein purified from Xenopus ovaries, and can be readily obtained in pure form and large quantity.
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PMID:High yield purification of active transcription factor IIIA expressed in E. coli. 195 78

The C-terminal domain (CTD) of the largest subunit of yeast RNA polymerase II contains 26-27 tandem copies of a conserved heptapeptide of unknown function. Yeast strains whose CTD contains ten heptamers are viable but defective for transcription of the INO1 gene and cold sensitive for growth. Deletion of the SIN1 gene, which codes for a DNA-binding protein that negatively regulates HO transcription, restores INO1 transcription and reduces the cold sensitivity of such strains. A SIN1 deletion suppresses the lethality of a CTD with nine heptamer repeats but not with seven repeats. These observations indicate a functional relationship between SIN1 and the CTD: the CTD might remove SIN1 from DNA, or removal of SIN1 may be a prerequisite for function of the CTD. The SWI1, SWI2, and SWI3 genes, whose products activate HO transcription by antagonizing SIN1, are also required for INO1 transcription and may assist the CTD. In addition, an intact CTD binds nonspecifically to DNA in vitro.
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PMID:A functional interaction between the C-terminal domain of RNA polymerase II and the negative regulator SIN1. 200 20

sigma 32, the product of the Escherichia coli rpoH locus, is an alternative RNA polymerase sigma factor utilized to express heat shock genes upon a sudden rise in temperature. E. coli K165 [rpoH165(Am) supC(Ts)] is temperature sensitive for growth and does not induce heat shock protein synthesis. We have isolated a locus from Rhizobium meliloti called suhR that allows E. coli K165 to grow at high temperature and induce heat shock protein synthesis. R. meliloti suhR mutants were viable and symbiotically effective. suhR was found to have no DNA or derived amino acid sequence similarity to the genes of previously sequenced sigma factors or other data base entries, although a helix-turn-helix DNA-binding protein motif is present. suhR did not restore the phenotypic defects of delta rpoH E. coli; suppression of the E. coli K165 phenotype is thus likely to involve E. coli sigma 32. Western immunoblots showed that suhR caused an approximately twofold elevation of sigma 32 levels in K165; RNA blots indicated that rpoH mRNA level and stability were not altered. Stabilization of sigma 32 protein and increased rpoH mRNA translation are thus the most probable mechanisms of suppression.
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PMID:Rhizobium meliloti suhR suppresses the phenotype of an Escherichia coli RNA polymerase sigma 32 mutant. 211 6

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