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 protein nitrogen regulator I (NRI)-phosphate is known to activate the initiation of transcription of the Escherichia coli glnA gene. This activation is facilitated by the binding of the protein to NRI-specific sites located upstream of the sigma 54-dependent glnA promoter. To determine whether binding of NRI-phosphate to upstream sites is sufficient for activation, we placed several promoters not normally activated by NRI-phosphate downstream of NRI binding sites and measured activation in intact cells and in an in vitro transcription system. We found that the sigma 70-dependent lac promoter was not activated, that the sigma 54-dependent Klebsiella pneumoniae nifH promoter was weakly activated, and that a nifH promoter altered in the RNA polymerase binding site was almost as well activated as the glnA promoter. We conclude that the sensitivity of the susceptible promoter depends on the presence of NRI binding sites, but that the presence of bound NRI-phosphate upstream of a promoter is not sufficient for activation of transcription by RNA polymerase. This activation is determined by the structure of the RNA polymerase binding site. We suggest that sigma 54-but not sigma 70-dependent promoters are susceptible to activation by NRI-phosphate and that the nucleotide sequence of the sigma 54-RNA polymerase binding site is an important determinant of the efficiency of activation.
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PMID:Role of the promoter in activation of transcription by nitrogen regulator I phosphate in Escherichia coli. 240 58

Nuclei were isolated from bloodstream forms of Trypanosoma brucei by nitrogen cavitation and sedimentation through percoll density gradients. Transcription studies with these nuclei in vitro demonstrated features not seen with other eukaryotes: RNA synthesis was much greater in the presence of Mn2+ than with Mg2+ and was sensitive to high concentrations (10-100 micrograms/ml) of alpha-amanitin at all salt concentrations tested (25-300 mM ammonium sulphate). RNA polymerase extracted from nuclei by sonication at high ionic strength chromatographed as a single peak, sensitive to high alpha-amanitin concentrations, on DEAE-sephadex under conditions which resolved the classic three RNA polymerase forms when rat liver nuclear extracts were used.
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PMID:Unusual RNA polymerase content of Trypanosoma brucei nuclei. 241 50

A new bacterial promoter type has been identified in the last few years. Originally designated as nif (= nitrogen fixation) or ntr (= nitrogen regulation) consensus promoter, it is now evident that this promoter occurs in many different bacterial species and is used not only for genes involved in nitrogen assimilation but also for genes determining many other unrelated metabolic functions. The general features of this type of promoter are (i) the conserved -24(GG)/-12(GC) consensus sequence, (ii) its recognition by a specific RNA polymerase sigma factor, sigma 54, which is encoded by the ntrA gene (synonyms: glnF, rpoN, rpoE), and (iii) the requirement for a transcriptional regulatory protein to activate the expression of the associated genes. In addition, many (but not all) of these genes possess a promoter-upstream activator sequence (enhancer) which is the target site for the binding of the activating protein and is required for maximal expression. In some cases, in which gene expression does not appear to be dependent on the presence of upstream binding sites, the activating protein may interact directly with the RNA polymerase-promoter complex. In conclusion, the expression from all -24/-12 consensus promoters known to date is positively controlled.
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PMID:The -24/-12 promoter comes of age. 251 36

The nitrogen regulatory (NtrC) protein of enteric bacteria, which binds to sites that have the properties of transcriptional enhancers, is known to activate transcription by a form of RNA polymerase that contains the NtrA protein (sigma 54) as sigma factor (referred to as sigma 54-holoenzyme). In the presence of adenosine triphosphate, the NtrC protein catalyzes isomerization of closed recognition complexes between sigma 54-holoenzyme and the glnA promoter to open complexes in which DNA in the region of the transcription start site is locally denatured. NtrC is not required subsequently for maintenance of open complexes or initiation of transcription.
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PMID:Function of a bacterial activator protein that binds to transcriptional enhancers. 256 95

The promoter region of the Pseudomonas aeruginosa pilin gene has a high degree of similarity to the nitrogen-regulated promoters of enteric bacteria. These promoters are recognized by the alternative sigma factor of RNA polymerase, termed RpoN (NtrA or GlnF). This observation suggested that the P. aeruginosa pilin gene may be transcribed by the RpoN-containing RNA polymerase. We, therefore, cloned the RpoN gene from P. aeruginosa into Escherichia coli (where it formed a functional product) and used that cloned gene to construct a mutant of P. aeruginosa that was insertionally inactivated in its RpoN gene. This mutant failed to synthesize pilin, indicating that the RpoN sigma factor is required for transcription of the pilin gene.
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PMID:Formation of pilin in Pseudomonas aeruginosa requires the alternative sigma factor (RpoN) of RNA polymerase. 256 76

Growth of cells of Escherichia coli in nitrogen-limited medium induces the formation of glutamine synthetase, product of the glnA gene, and of other proteins that facilitate the assimilation of nitrogen-containing compounds. Transcription from the glnAp2 promoter of the glnALG operon requires the phosphorylation of nitrogen regulator I (NRI) and, for optimal transcription, the binding of NRI-phosphate to two sites that can be over 1,000 base pairs from the binding site for RNA polymerase. In other procaryotic genes, placement of an activator-binding site further upstream from the start site of transcription diminishes expression. To determine how NRI-phosphate activates transcription and why NRI-dependent transcription differs from activation in other systems, we constructed recombinant plasmids with small alterations between the binding sites for NRI-phosphate and RNA polymerase and between the two high-affinity NRI-binding sites. We demonstrate that tightly bound NRI-phosphate activated transcription from either side of the DNA helix when at least 30 base pairs separated NRI-phosphate from RNA polymerase. In contrast, activation from a partial NRI-binding site was effective only from one side of the DNA. We also observed that glnA expression was optimal when the two high-affinity NRI-binding sites were on the same side of the DNA helix. We explain these results on the basis of a hypothesis that a contact between RNA polymerase and NRI-phosphate bound to an upstream site determines the rate of glnA transcription.
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PMID:Activation of glnA transcription by nitrogen regulator I (NRI)-phosphate in Escherichia coli: evidence for a long-range physical interaction between NRI-phosphate and RNA polymerase. 257 9

A set of the periodically regulated flagellar (fla) genes of Caulobacter crescentus contain conserved promoter sequence elements at -24 and -12 that are very similar to the sequence of the nitrogen assimilation (Ntr) and nitrogen fixation (Nif) promoters of enteric bacteria and Rhizobium spp. Transcription from Ntr and Nif promoters requires RNA polymerase containing sigma 54 instead of the usual sigma 70 and, in the case of the Ntr promoters, is activated by the transcription factors NRI and NRII. We have now demonstrated that the C. crescentus flbG and flaN promoters, which contain the Ntr/Nif type of consensus sequence, are utilized by purified Escherichia coli sigma 54 RNA polymerase (E sigma 54) in the presence of NRI and NRII but not by the purified sigma 70 RNA polymerase (E sigma 70) of E. coli. Oligonucleotide-generated flbG promoter deletions that removed the highly conserved GG dinucleotide at -24 or the GC dinucleotide at -12 or altered the spacing between the -24 and -12 sequence elements prevented utilization of the flbG promoter by the E. coli E sigma 54. Transversions of T to G at positions -26 and -15 also inactivated flbG promoter function in the E. coli cell-free transcription system, while a transition of G to A at position -16 in the nonconserved spacer region had no effect. The C. crescentus flaO and flbF promoters, which do not contain the Ntr/Nif-type promoter consensus sequence, were not utilized by either purified E sigma 54 or E sigma 70 from E. coli. Our results help to define the features of the Ntr/Nif-type consensus sequence required for promoter utilization by purified E. coli E sigma 54 and support the idea that C. crescentus may contain a specialized polymerase with similar promoter specificity required for expression of a set of fla genes.
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PMID:Escherichia coli sigma 54 RNA polymerase recognizes Caulobacter crescentus flbG and flaN flagellar gene promoters in vitro. 264 97

Complementation of Rhizobium leguminosarum dct mutants with a cosmid bank yielded Rhizobium meliloti homologs of the dctA, dctB, and dctD genes. The genes dctB and dctD are thought to form a two-component system which responds to the presence of C4-dicarboxylates to regulate expression of a transport protein encoded by dctA. DNA sequence analysis showed that dct coding and intergenic regions, including putative binding sites for the dctD protein and sigma 54-RNA polymerase, were highly conserved between these two Rhizobium species. Mutation of R. meliloti dctD showed that it was not essential for symbiotic nitrogen fixation but was needed for growth on succinate and the expression of a dctA-lacZ fusion gene in free-living cells. Hybridization of R. meliloti genomic DNA with probes representing the central portion of dctD potentially identified more than 20 similar regulatory genes, all of which are likely to depend upon the alternative sigma factor encoded by rpoN and stimulate transcription in a manner very similar to ntrC activation of glnA in enteric bacteria.
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PMID:Conservation between coding and regulatory elements of Rhizobium meliloti and Rhizobium leguminosarum dct genes. 279 24

The NTRC protein (ntrC product) of enteric bacteria activates transcription of nitrogen-regulated genes by a holoenzyme form of RNA polymerase that contains the ntrA product (sigma 54) as sigma factor. Although unmodified NTRC will bind to DNA, it must be phosphorylated to activate transcription. Both phosphorylation and dephosphorylation of NTRC occur in the presence of the NTRB protein (ntrB product). We here demonstrate rigorously that it is the NTRB protein that is a protein kinase by showing that NTRB can phosphorylate itself, whereas NTRC cannot. Phosphorylated NTRC (NTRC-P) is capable of autodephosphorylation with a first-order rate constant of 0.14-0.19 min-1 (t 1/2 of 5.0-3.6 min) at 37 degrees C. In addition, there is regulated dephosphorylation of NTRC-P. By contrast to the autophosphatase activity, regulated dephosphorylation requires three components in addition to NTRC-P: the PII regulatory protein, NTRB, and ATP. NTRC is phosphorylated within its amino-terminal domain, which is conserved in one partner of a number of two-component regulatory systems in a wide variety of eubacteria. A purified amino-terminal fragment of NTRC (approximately equal to 12.5 kDa) is sufficient for recognition by NTRB and is autodephosphorylated at the same rate as the native protein.
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PMID:Protein kinase and phosphoprotein phosphatase activities of nitrogen regulatory proteins NTRB and NTRC of enteric bacteria: roles of the conserved amino-terminal domain of NTRC. 283 25

We have shown that the purified glnF (ntrA) product of Escherichia coli binds to core RNA polymerase. Together these proteins initiated transcription at the nitrogen-regulated promoter glnAp2 on a supercoiled template. The initiation of transcription at glnAp2 on a linear template required in addition NRI, the product of glnG (ntrC), and NRII2302, the product of a mutant allele of glnL (ntrB). These results identify the glnF product as a new sigma factor specifically required for the transcription of nitrogen-regulated and of nitrogen-fixation promoters. We propose rpoN as the proper designation for glnF, and sigma 60 for its product. Our results indicate that sigma 60 RNA polymerase recognizes the nitrogen-regulated/nitrogen-fixation promoter consensus sequence C-T-G-G-Y-A-Y-R-N4-T-T-G-C-A. Initiation of transcription in the intact cell appears to require in addition the active form of NRI, the product of glnG. Conversion of NRI to its active form is apparently brought about by NRII, the product of glnL, in response to nitrogen deprivation.
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PMID:Transcription of glnA by purified Escherichia coli components: core RNA polymerase and the products of glnF, glnG, and glnL. 286 43

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