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 NTRC protein of enteric bacteria is an enhancer-binding protein that activates transcription in response to limitation of combined nitrogen. NTRC activates transcription by catalyzing formation of open complexes by RNA polymerase (sigma 54 holoenzyme form) in an ATP-dependent reaction. To catalyze open complex formation, NTRC must be phosphorylated. We show that phosphorylated NTRC has an ATPase activity, and we present biochemical and genetic evidence that NTRC must hydrolyze ATP to catalyze open complex formation. It is likely that all activators of sigma 54 holoenzyme have an ATPase activity.
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PMID:The phosphorylated form of the enhancer-binding protein NTRC has an ATPase activity that is essential for activation of transcription. 183 69

The filamentous cyanobacterium Anabaena sp. strain PCC 7120 responds to combined nitrogen deprivation by forming specialized nitrogen-fixing cells at regular intervals along the filament. Genetic and biochemical studies have indicated that regulation of gene expression during differentiation occurs at the transcriptional level. As part of a characterization of RNA polymerase during differentiation, the gene encoding the 52-kDa principal sigma factor of the Anabaena sp. strain PCC 7120 vegetative-cell RNA polymerase was isolated by using an oligonucleotide probe based on the sequence of the N-terminal seven amino acids of the purified protein. sigA codes for a 390-amino-acid polypeptide that has a predicted molecular weight of 45,641. The amino acid sequence of the polypeptide encoded by sigA contains four regions corresponding to conserved domains of the principal RNA polymerase sigma factors of Escherichia coli (sigma 70) and Bacillus subtilis (sigma 43). Thus, although the subunit composition of cyanobacterial RNA polymerase core differs from that of other eubacteria (G. J. Schneider and R. Haselkorn, J. Bacteriol. 170:4136-4140, 1988), the principal sigma factor of at least one cyanobacterium is typically eubacterial. In contrast to sigma 70 and sigma 43 operon organization, sigA is monocistronic and encodes two transcripts of 1.7 and 2.2 kb. The abundance of the 1.7-kb transcript remains constant under both nitrogen-replete and nitrogen-limiting conditions, whereas the 2.2-kb transcript is induced following the removal of combined nitrogen. Continued or enhanced transcription of sigA under nitrogen starvation conditions is consistent with the observation that the principal RNA polymerase in differentiating cells contains SigA.
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PMID:Isolation and characterization of the gene encoding the principal sigma factor of the vegetative cell RNA polymerase from the cyanobacterium Anabaena sp. strain PCC 7120. 190 66

Nucleophosmin/B23 is a nucleolar phosphoprotein which forms oligomers. To determine the domain essential for oligomer formation, various deletion and point mutation clones of nucleophosmin/B23 were constructed. Nucleophosmin/B23 and the mutant proteins were produced by (a) coupled in vitro transcription and translation and (b) expression in Escherichia coli with T7 RNA polymerase expression vector (pET-8c). Nucleophosmin/B23 synthesized in vitro has the same peptide map as that synthesized in HeLa cells. Similarly, it formed oligomers which could be detected in SDS/PAGE and were cross-linked with nitrogen mustard in vivo. Substitution of Met5, Met7, and Met9 with Leu or deletion of five amino acids at the C-terminus abolished the oligomerization. Deletion of portions of amino acids in the middle of the molecule (amino acid residues 83-152, 117-186 and 185-240) had little effect on the oligomerization. Co-expression of the N- and C-terminal mutant clones in vitro did not produce oligomers. These results indicate that intra-molecular interactions with both the N- and C-terminal domains are essential for oligomer formation.
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PMID:Formation of nucleophosmin/B23 oligomers requires both the amino- and the carboxyl-terminal domains of the protein. 191 43

The nitrogen regulatory protein NtrC of enteric bacteria activates transcription of the glnA gene by catalyzing isomerization of closed complexes between RNA polymerase and the glnA promoter to open complexes. NtrC binds to sites upstream of glnA that have properties of eukaryotic transcriptional enhancers. NtrC-binding sites were found to facilitate open complex formation when these sites and the glnA promoter were located on different rings of a singly linked catenane, but not when the two rings were decatenated. The results provide evidence that NtrC contacts RNA polymerase-promoter complexes in a process mediated by formation of a DNA loop. NtrC-binding sites serve to tether NtrC near the glnA promoter, thereby increasing the frequency of collisions between NtrC and polymerase-promoter complexes.
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PMID:A bacterial enhancer functions to tether a transcriptional activator near a promoter. 197 Apr 41

The gene encoding glutamine synthetase (GS), glnA, was cloned from Azotobacter vinelandii on a 6-kb EcoRI fragment that also carries the ntrBC genes. The DNA sequence of 1,952 bp including the GS-coding region was determined. An open reading frame of 467 amino acids indicated a gene product of Mr 51,747. Transcription of glnA occurred from a C residue located 32 bases upstream of an ATG considered to be the initiator codon because (i) it had a nearby potential ribosome-binding site and (ii) an open reading frame translated from this site indicated good N-terminal homology to 10 other procaryotic GSs. Sequences similar to the consensus RNA polymerase recognition sites at -10 and -35 were present at the appropriate distance upstream of the transcription initiation site. As expected from earlier genetic studies indicating that expression of A. vinelandii glnA did not depend on the rpoN (ntrA; sigma 54) gene product, no sigma 54 recognition sequences were present, nor was there significant regulation of glnA expression by fixed nitrogen. Repeated attempts to construct glutamine auxotrophs by recombination of glnA insertion mutations were unsuccessful, Although the mutated DNA could be found by hybridization experiments in drug-resistant A. vinelandii transformants, the wild-type glnA region was always present. These results suggest that glnA mutations are lethal in A. vinelandii. In [14C]glutamine uptake experiments, very little glutamine was incorporated into cells, suggesting that glutamine auxotrophs are nonviable because they cannot be supplied with sufficient glutamine to support growth.
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PMID:Molecular analysis of the Azotobacter vinelandii glnA gene encoding glutamine synthetase. 197 37

Recognition of -24/-12-type promoters by RNA polymerase requires a special sigma factor, sigma 54 (RpoN NtrA GlnF). In the nitrogen-fixing soybean symbiont Bradyrhizobium japonicum, two functional, highly conserved rpoN genes (rpoN1 and rpoN2) were identified and sequenced. The two predicted B. japonicum RpoN protein sequences were 87% identical, and both showed different levels of homology to the RpoN proteins of other bacteria. Downstream of rpoN2 (but not of rpoN1), two additional open reading frames were identified that corresponded to open reading frames located at similar positions in Klebsiella pneumoniae and Pseudomonas putida. Both B. japonicum rpoN genes complemented the succinate- and nitrate-negative phenotypes of a Rhizobium meliloti rpoN mutant. B. japonicum strains carrying single or double rpoN mutations were still able to utilize C4-dicarboxylates as a carbon source and histidine, proline, or arginine as a nitrogen source, whereas the ability to assimilate nitrate required expression of at least one of the two rpN genes. In symbiosis both rpoN genes could replace each other functionally. The rpoN1/2 double mutant induced about twice as many nodules on soybeans as did the wild type, and these nodules lacked nitrogen fixation activity completely. Transcription of a nifH'-'lacZ fusion was not activated in the rpoN1/2 mutant background, whereas expression of a fixR'-'lacZ fusion in this mutant was affected only marginally. By using rpoN'-'lacZ fusions, rpoN1 expression was shown to be activated at least sevenfold in microaerobiosis as compared with that in aerobiosis, and this type of regulation involved fixLJ. Expression of rpoN2 was observed under all conditions tested and was increased fivefold in an rpoN2 mutant. The data suggested that the rpoN1 gene was regulated in response to oxygen, whereas the rpoN2 gene was negatively autoregulated.
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PMID:Bradyrhizobium japonicum has two differentially regulated, functional homologs of the sigma 54 gene (rpoN). 199 12

The glnHPQ operon of Escherichia coli encodes components of the high-affinity glutamine transport system. One of the two promoters of this operon, glnHp2, is responsible for expression of the operon under nitrogen-limiting conditions. The general nitrogen regulatory protein (NRI) binds to two overlapping sites centered at -109 and -122 from the transcription start site and, when phosphorylated, activates transcription of glnHp2 by catalyzing isomerization of the closed sigma 54-RNA polymerase promoter complex to an open complex. The DNA-bending protein integration host factor (IHF) binds to a site immediately upstream of glnHp2 and enhances the activation of open complex formation by NRI phosphate. The NRI-binding sites can be moved several hundred base pairs further upstream without altering the ability of NRI phosphate to activate open complex formation. We propose that the IHF-induced bend can facilitate or obstruct the interaction between NRI phosphate and the closed complex depending on the relative positions of NRI phosphate and sigma 54-RNA polymerase on the DNA.
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PMID:Role of integration host factor in the regulation of the glnHp2 promoter of Escherichia coli. 200 Mar 72

The product of the rpoN gene is an alternative sigma factor of RNA polymerase which is required for transcription of a number of genes in members of the family Enterobacteriaceae, including those that specify enzymes of nitrogen assimilation, amino acid uptake, and degradation of a variety of organic molecules. We have previously shown that transcription of the pilin gene of Pseudomonas aeruginosa also requires RpoN (K. S. Ishimoto and S. Lory, Proc. Natl. Acad. Sci. USA 86:1954-1957, 1989) and have undertaken a more extensive survey of genes under RpoN control. Strains of P. aeruginosa that carry an insertionally inactivated rpoN gene were constructed and shown to be nonmotile because of the inability of these mutants to synthesize flagellin. The mutation in rpoN had no effect on expression of extracellular polypeptides, outer membrane proteins, and the alginate capsule. However, the rpoN mutants were glutamine auxotrophs and were defective in glutamine synthetase, indicating defects in nitrogen assimilation. In addition, the P. aeruginosa rpoN mutants were defective in urease activity. These findings indicate that the sigma factor encoded by the rpoN gene is used by P. aeruginosa for transcription of a diverse set of genes that specify biosynthetic enzymes, degradative enzymes, and surface components. These rpoN-controlled genes include pili and flagella which are required for full virulence of the organism.
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PMID:The rpoN gene product of Pseudomonas aeruginosa is required for expression of diverse genes, including the flagellin gene. 215 9

The nucleotide (nt) sequence of the Rhizobium leguminosarum nifH promoter region contains a consensus promoter, a consensus upstream activator sequence (UAS), a pseudo (psi) promoter and a psi UAS. We mapped the transcription start point for the consensus promoter sequence by primer extension. This promoter differs from the consensus in one of the four supposedly invariant nt and can be activated by the Klebsiella pneumoniae nifA product in Escherichia coli. Under these conditions the psi promoter and psi UAS do not function. A low-copy-number plasmid construct containing the psi UAS as well as the consensus UAS delayed the onset of symbiotic nitrogen fixation in nodules induced on Pisum sativum. Studies of high-copy-number nifH promoter constructs showed that partial deletion of the consensus UAS does not alter the ability to inhibit nitrogen fixation by titration of NifA suggesting that NifA can also complex with RNA polymerase containing the alternative sigma-factor RpoN.
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PMID:The nifH promoter region of Rhizobium leguminosarum: nucleotide sequence and promoter elements controlling activation by NifA protein. 218 38

The regulatory protein NIFA activates transcription of nitrogen fixation (nif) operons by the sigma 54 holoenzyme form of RNA polymerase. NIFA from Klebsiella pneumoniae activates transcription from the nifH promoter in vitro; in addition, the integration host factor, IHF, binds between the nifH promoter and an upstream binding site for NIFA. We demonstrate here that IHF greatly stimulates NIFA-mediated activation of nifH transcription in vitro and thus that the two factors are functionally synergistic. Electron micrographs indicate that IHF bends the DNA in the nifH promoter regulatory region. Although IHF binds close to the nifH promoter, it does not directly stimulate binding of sigma 54 holoenzyme. Rather, the IHF-induced bend may facilitate productive contacts between NIFA and sigma 54 holoenzyme that lead to the formation of open complexes. IHF binds to nif promoter regulatory regions from a variety of organisms within the phylum "purple bacteria," suggesting a general ability to stimulate NIFA-mediated activation of nif transcription.
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PMID:The integration host factor stimulates interaction of RNA polymerase with NIFA, the transcriptional activator for nitrogen fixation operons. 220 75

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