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 alternative sigma factor, RpoN (sigma 54) is responsible for recruiting core RNA polymerase to the promoters of genes required for diverse physiological functions in a variety of eubacterial species. The RpoN protein in Rhodobacter capsulatus is a putative sigma factor specific for nitrogen fixation (nif) genes. Insertional mutagenesis was used to define regions important for the function of the R. capsulatus RpoN protein. Insertions of four amino acids in the predicted helixturn-helix or in the highly conserved C-terminal eight amino acid residues (previously termed the RpoN box), and an in-frame deletion of the glutamine-rich N-terminus completely inactivated the R. capsulatus RpoN protein. Two separate insertions in the second hydrophobic heptad repeat, a putative leucine zipper, resulted in a partially functional RpoN protein. Eight other linkers in the rpoN open reading frame (ORF) resulted in a completely or partially functional RpoN protein. The rpoN gene in R. capsulatus is downstream from the nifHDKU2 genes, in a nifU2-rpoN operon. Results of genetic experiments on the nifU2-rpoN locus show that the rpoN gene is organized in a nifU2-rpoN superoperon. A primary promoter directly upstream of the rpoN ORF is responsible for the initial expression of rpoN. Deletion analysis and insertional mutagenesis were used to define the primary promoter to 50 bp, between 37 and 87 nucleotides upstream of the predicted rpoN translational start site. This primary promoter is expressed constitutively with respect to nitrogen, and it is necessary and sufficient for growth under nitrogen-limiting conditions typically used in the laboratory. A secondary promoter upstream of nifU2 is autoactivated by RpoN and NifA to increase the expression of rpoN, which ultimately results in higher expression of RpoN-dependent genes. Moreover, rpoN expression from this secondary promoter is physiologically beneficial under certain stressful conditions, such as nitrogen-limiting environments that contain high salt (> 50 mM NaCl) or low iron (< 400 nM FeSO4).
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PMID:Structure and expression of the alternative sigma factor, RpoN, in Rhodobacter capsulatus; physiological relevance of an autoactivated nifU2-rpoN superoperon. 814 46

FixJ is a phosphorylatable 'response regulator' controlling the transcription of the key nitrogen fixation genes nifA and fixK in Rhizobium meliloti. Sequence and genetic analyses indicated that FixJ comprises an N-terminal phosphorylatable regulatory domain, FixJN, and a C-terminal transcriptional activator domain, FixJC. We have now overexpressed and purified the FixJC protein and show that it is fully active in an in vitro transcription system with purified RNA polymerase. FixJC appeared to act synergistically with RNA polymerase at the nifA promoter. Furthermore FixJC was more active in vitro than the full-length dephosphorylated FixJ protein. Therefore activity of FixJC is inhibited by FixJN within the FixJ protein. This inhibition is relieved by phosphorylation of FixJN. Such a negative mode of intramolecular signal transduction may be generalizable to other response regulators.
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PMID:Intramolecular signal transduction within the FixJ transcriptional activator: in vitro evidence for the inhibitory effect of the phosphorylatable regulatory domain. 820 54

The prokaryotic enhancer-binding protein NifA stimulates transcription at a distance by binding to sequences upstream of nitrogen fixation (nif) promoters and catalyzing the formation of open promoter complexes by RNA polymerase containing the alternative sigma factor, sigma 54. The activity of NifA in vivo is modulated by the negative regulatory protein NifL in response to environmental oxygen and fixed nitrogen. To date, a detailed biochemical analysis of these proteins from the model diazotroph Klebsiella pneumoniae has been hindered by their insolubility. We have now purified NifA and NifL from Azotobacter vinelandii in their native form. NifA is competent in specific DNA binding, transcriptional activation, and response to negative regulation by NifL in vitro. In contrast to the conserved mechanism of phosphotransfer demonstrated by other two-component regulatory systems, our results support a model in which NifL regulates the activity of NifA via a protein-protein steric block interaction rather than a catalytic modification of NifA.
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PMID:Purification and in vitro activities of the native nitrogen fixation control proteins NifA and NifL. 820 22

Oxygen concentration regulates the expression of nitrogen fixation genes in the symbiotic bacterium Rhizobium meliloti. We demonstrate that two proteins, FixL and FixJ, that belong to the two-component family of regulatory proteins are necessary and sufficient for oxygen-regulated in vitro transcription of the two key regulatory genes, nifA and fixK. We show directly that FixJ is a transcriptional activator, working in conjunction with the RNA polymerase sigma 70 holoenzyme. Addition of FixL122, a soluble form of the sensor FixL protein, to the transcription assay enhanced FixJ transcriptional activity in response to low oxygen concentration. This enhancement of FixJ activity was correlated with FixJ phosphorylation.
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PMID:Oxygen-regulated in vitro transcription of Rhizobium meliloti nifA and fixK genes. 822 29

DNA containing the lac UV5 promoter was alkylated using bifunctional sulfur and nitrogen mustards and a monofunctional sulfur mustard. The alkylation sites were mapped using Taq polymerase, and the effect of alkylation on the formation of the DNA-RNA polymerase complex was determined using gel retardation. Alkylation was observed at all G residues in the template strand. Exposure of the alkylated DNA to Escherichia coli RNA polymerase resulted in the formation of a DNA-enzyme complex that was more stable, prior to initiation, than the complex formed with nonalkylated DNA. The DNA-RNA polymerase complex formed with the alkylated DNA also demonstrated decreased ability to progress along the full length of the DNA template. These observations show that, in addition to inducing transcriptional blockages, mustards also influence the interaction between RNA polymerase and its promoter. The ability to interfere with protein-DNA interactions may contribute significantly to the effects of these compounds in eukaryotic systems with their complex array of transcription factors.
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PMID:Effect of alkylating agents on initiation and elongation of the lac UV5 promoter. 824 Nov 38

In the free-living diazotroph Klebsiella pneumoniae, the NifA protein is required for transcription of all nif (nitrogen fixation) operons except the regulatory nifLA operon itself. NifA activates transcription of nif operons by the alternative holoenzyme form of RNA polymerase, sigma 54 holoenzyme. In vivo, NifL is known to antagonize the action of NifA in the presence of molecular oxygen or combined nitrogen. We now demonstrate inhibition by NifL in vitro in both a coupled transcription-translation system and a purified transcription system. Crude cell extracts containing NifL inhibit NifA activity in the coupled system, as does NifL that has been solubilized with urea and allowed to refold. Inhibition is specific to NifA in that it does not affect activation by NtrC, a transcriptional activator homologous to NifA, or transcription by sigma 70 holoenzyme. Renatured NifL also inhibits transcriptional activation by a maltose-binding protein fusion to NifA in a purified transcription system, indicating that no protein factor other than NifL is required. Since inhibition in the purified system persists anaerobically, our NifL preparation does not sense molecular oxygen directly.
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PMID:In vitro activity of NifL, a signal transduction protein for biological nitrogen fixation. 824 38

The NIFA protein of Klebsiella pneumoniae is required for transcription of all nif (nitrogen fixation) operons except the regulatory nifLA operon itself. NIFA activates transcription of nif operons by the alternative holoenzyme form of RNA polymerase, sigma 54-holoenzyme, in a nucleoside triphosphate (NTP)-dependent manner. NIFL antagonizes the action of NIFA in the presence of molecular oxygen or combined nitrogen. The NIFA protein of K. pneumoniae is composed of three domains: an N-terminal domain with unclear function, a central catalytic domain, and a C-terminal DNA-binding domain. We report that the isolated central domain of NIFA activates transcription in vitro and that this activation requires NTP with a hydrolyzable beta-gamma bond, as does activation by intact NIFA. Transcriptional activation by the isolated central domain has the heat lability characteristic of intact NIFA and is inhibited by NIFL. The central domain has an NTPase activity that is also heat-labile but is not inhibited by NIFL. Taken together, these results imply that NIFL interferes with contact between NIFA and sigma 54-holoenzyme.
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PMID:The isolated catalytic domain of NIFA, a bacterial enhancer-binding protein, activates transcription in vitro: activation is inhibited by NIFL. 827 50

The NTRC protein of enteric bacteria is an enhancer-binding protein that activates transcription by the sigma 54-holoenzyme form of RNA polymerase under nitrogen-limiting conditions. In vitro NTRC must be phosphorylated to catalyze ATP hydrolysis and activate transcription. The site of phosphorylation of NTRC from Salmonella typhimurium is Aspartate 54, which lies in the amino-terminal regulatory domain of the protein. We used site-directed mutagenesis to make "conservative" substitutions at residue 54 to alanine, asparagine, and glutamate, and examined the properties of the mutant NTRC proteins in vitro and in vivo. In vitro none of them was detectably phosphorylated, as expected if D54 is, in fact, the sole site of phosphorylation. D54A and D54N did not activate transcription of glnA but, interestingly, D54E activated constitutively. Activation by D54E was partial compared to that by phosphorylated wild-type NTRC. Combining D54A or D54N with S160F, a change in the central domain of NTRC that partially bypasses the requirement for phosphorylation, yielded doubly mutant proteins that were as active as a form carrying S160F alone, indicating that the changes in D54 did not adversely affect the function of the remainder of NTRC. Combining D54E with S160F increased the levels of constitutive ATPase activity and transcriptional activation above those of mutant NTRC proteins carrying either single change alone. We conclude that phosphorylation of aspartate 54 is required to activate NTRC and postulate that the D54E mutation mimics phosphorylation, thereby allowing NTRC to hydrolyze ATP and activate transcription. Phenotypes of mutant strains encoding NTRC proteins with substitutions at D54 indicated that phosphorylation of NTRC at position 54 was necessary for normal growth in the absence of glutamine and that such phosphorylation occurred to some extent even in the absence of NTRB.
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PMID:Glutamate at the site of phosphorylation of nitrogen-regulatory protein NTRC mimics aspartyl-phosphate and activates the protein. 833 71

Many of the symbiotic nitrogen-fixation genes in the soybean root nodule bacterium, Bradyrhizobium japonicum, are transcribed from -24/-12 promoters that are recognized by the sigma 54-RNA polymerase and activated by the transcriptional regulator protein, NifA. Several lines of evidence suggest that the B. japonicum genome has more than those seven NifA-regulated promoters which were characterized previously. Here, we present a strategy aimed at the cloning of new NifA-activated promoters. It makes use of (i) a promoter-probe vector into which random B. japonicum genomic fragments were cloned in front of a promoterless reporter gene and (ii) a screening procedure that allowed us to distinguish constitutive promoters from promoters that were specifically activated by NifA under microaerobic or anaerobic conditions. With certain modifications, the system may be generally applicable to clone positively regulated, anaerobically induced genes. A novel NifA-dependent promoter region (ndp) of B. japonicum was found by these means. The transcription start point was mapped, and its 5'-flanking DNA carried a -24/-12-type promoter sequence plus potential binding sites for NifA and integration host factor. Further transcript analyses confirmed that maximal transcription from this promoter occurred only in the presence of NifA and sigma 54 during anaerobic growth of B. japonicum. In Escherichia coli, expression of beta-galactosidase derived from a transcriptional ndp::lacZ fusion was activated 11-fold by B. japonicum NifA, and this activation also required sigma 54 but was independent of NtrC. The DNA around ndp shared no similarity with known sequences in databases.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Use of a promoter-probe vector system in the cloning of a new NifA-dependent promoter (ndp) from Bradyrhizobium japonicum. 833 58

We have measured the DNA damage formation and repair in the ribosomal and the dihydrofolate reductase (DHFR) genes after treatment of hamster cells with different types of DNA damaging agents. In mammalian cells, the ribosomal DNA (rDNA) is transcribed by RNA polymerase I, whereas the DHFR is transcribed by RNA polymerase II, whereas the DHFR is transcribed by RNA polymerase II. Cells were treated with agents that induce different types of lesions, and that are known to be repaired via different pathways. We used UV (254 nm) irradiation, treatment with cisplatin and treatment with the alkylating agents nitrogen mustard (HN2) and methyl methanesulphonate (MMS). UV induced pyrimidine dimers were detected with the enzyme T4 endonuclease V, which creates nicks at the dimer sites; the breaks are then resolved and identified by denaturing electrophoresis and Southern blot. Intrastrand adducts formed by the alkylating agents HN2 and MMS were quantitated by generating strand breaks at abasic sites after neutral depurination. Interstrand crosslinks (ICL) formed by HN2 and cisplatin were detected by a denaturation-reannealing reaction before neutral agarose gel-electrophoresis. We find that the repair of the pyrimidine dimers is significantly less efficient in the RNA polymerase I transcribed rDNA genes than in RNA polymerase II transcribed DHFR gene at 8 and 24 h after irradiation. ICL and intrastrand adducts induced by HN2 are also removed more slowly from the rDNA than from the DHFR gene. In contrast, MMS induced intrastrand adducts and cisplatin induced ICL are repaired equally efficiently in the RNA polymerase I and RNA polymerase II transcribed genes. We conclude that for some types of DNA damage, there is less repair in the ribosomal genes than in the DHFR; but for other DNA lesions there is no difference. The difference in repair efficiency between the rDNA and the DHFR genes may reflect the different RNA polymerase involved in their transcription. It may, however, alternatively, reflect the different nuclear localization of these genes.
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PMID:Repair of ribosomal RNA genes in hamster cells after UV irradiation, or treatment with cisplatin or alkylating agents. 835 43

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