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)

DNA-dependent RNA polymerase (EC 2.7.7.6) from Rhizobium japonicum was purified. The subunit structure was found to be beta beta' alpha 2 alpha, with the following apparent molecular weights determined by electrophoresis: Mr (beta and beta') 150,000 each, Mr (sigma) 96,000, Mr (alpha) 40,000, Mr (holoenzyme) 490,000, Mr (core enzyme) 380,000. The recovery of sigma was 28%. RNA polymerase from aerobically grown R. japonicum cells and from nitrogen-fixing cells have the same electrophoretic properties suggesting that no chemical modification of the enzyme occurs when cells undergo this metabolic differentiation. The enzyme is Mg2+-dependent, rifampicin-sensitive, and has optimal activity at alkaline pH (8--10) and at 35--40 degrees C. It binds strongly to bacteriophage T7 promoters, weakly to antibiotic resistance genes, and not at all to cloned R. japonicum nif DNA. Preliminary in vitro transcription experiments, including nif DNA as template, revealed that additional factors may be required for selective transcription from promoters.
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PMID:RNA polymerase from Rhizobium japonicum. 663 71

Model compounds for the Zn sites of the beta' and the beta subunits in RNA polymerase [1] were synthesized. Single crystal structures and X-ray absorbtion spectroscopy measurements for these two model complexes are reported. In Zn(C6H12OS2)2(ClO4)2, the Zn is coordinated by four sulfur and two oxygen atoms. The average Zn-S bond length is 2.514 A and the Zn-O bond length is 2.089 A, which are similar to these bond distances reported for the Zn site in the beta' subunit of RNA polymerase. In Zn(C3H6NS2)2(C3H4N2), the Zn atom is coordinated by four sulfur atoms and one nitrogen atom of an imidazole group. The average of the Zn-S bond length is 2.469 A and the Zn-N bond length is 2.009 A, which are also similar to the Zn-S and Zn-N bonds in the beta subunits of RNA polymerase.
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PMID:Synthesis and structures of Zn(C6H12OS2)2(ClO4)2 and Zn(C3H6NS2)2(C3H4N2)--model compounds for the Zn sites in RNA polymerase. 750 87

Recently, it has been demonstrated that nitrogen mustard-induced N-alkylpurines are excised rapidly from actively transcribing genes, while they persist longer in noncoding regions and in the genome overall. It was suggested that transcriptional activity is implicated as a regulatory element in the efficient removal of lesions. By treating cells or not with the transcription inhibitor alpha-amanitin, we have explored whether ongoing activity of RNA polymerase II was coordinately related to proficient repair of nitrogen mustard-induced alkylation products in the actively transcribed dihydrofolate reductase gene in the Chinese hamster ovary B11 cells. Nuclear run-off transcription analysis verified that alpha-amanitin completely and selectively inhibited transcription by RNA polymerase II. At the drug exposure examined, nitrogen mustard induced DNA damage capable of a complete transcription termination in the RNA polymerase II-transcribed dihydrofolate reductase gene and reduced 28S rDNA transcription by a factor of 7.9. The transcription activity did partially recover following reincubation in drug-free medium; this recovery was about 34 and 76% of ribosomal 28S gene transcripts and dihydrofolate reductase gene transcripts, respectively, after 6 h of repair incubation. alpha-Amanitin significantly inhibited the removal of nitrogen mustard-induced N-alkylpurines in the 5'-half of the essential, constitutively active dihydrofolate reductase gene, while no effect of alpha-amanitin was observed on the lesion removal from a noncoding region 3'-flanking to the gene and from the genome overall. In the actively transcribed gene region, about 77% of N-alkylpurines were removed 21 h following drug exposure of cells not treated with alpha-amanitin and about 47% in 21 h in alpha-amanitin treated cells. The global semiconservative replication seemed unaffected by the alpha-amanitin treatment. From these results we suggest that gene-specific repair of nitrogen mustard-induced N-alkylpurines is dependent on ongoing activity of the transcribing RNA polymerase II. The findings are discussed in terms of the current ideas about the mechanism of preferential DNA repair.
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PMID:Ongoing activity of RNA polymerase II confers preferential repair of nitrogen mustard-induced N-alkylpurines in the hamster dihydrofolate reductase gene. 750 96

The nac gene of Klebsiella aerogenes encodes a bifunctional transcription factor that activates or represses the expression of several operons under conditions of nitrogen limitation. In experiments with purified components, transcription from the nac promoter was initiated by sigma 54 RNA polymerase and was activated by the phosphorylated form of nitrogen regulator I (NRI) (NtrC). The activation of the nac promoter required a higher concentration of NRI approximately P than did the activation of the Escherichia coli glnAp2 promoter, and both the promoter and upstream enhancer element contributed to this difference. The nac promoter had a lower affinity for sigma 54 RNA polymerase than did glnAp2, and uninitiated competitor-resistant transcription complexes formed at the nac promoter decayed to competitor-sensitive complexes at a greater rate than did similar complexes formed at the glnAp2 promoter. The nac enhancer, consisting of a single high-affinity NRI-binding site and an adjacent site with low affinity for NRI, was less efficient in stimulating transcription than was the glnA enhancer, which consists of two adjacent high-affinity NRI-binding sites. When these binding sites were exchanged, transcription from the nac promoter was increased and transcription from the glnAp2 promoter was decreased at low concentrations of NRI approximately P. Another indication of the difference in the efficiency of these enhancers is that although activation of a nac promoter construct containing the glnA enhancer was relatively insensitive to subtle alterations in the position of these sites relative to the position of the promoter, activation of the natural nac promoter or a nac promoter construct containing only a single high-affinity NRI approximately P binding site was strongly affected by subtle alterations in the position of the NRI approximately P binding site(s), indicating a face-of-the-helix dependency for activation.
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PMID:Activation of transcription initiation from the nac promoter of Klebsiella aerogenes. 755 38

Transcription of the nitrogen-regulated nac promoter of Klebsiella aerogenes requires sigma54 RNA polymerase, is activated by the phosphorylated form of the transcription factor nitrogen regulator I (NRI) (NtrC), and is repressed by the product of the nac gene, Nac. Nac protects a large portion of the nac control region, extending from positions -130 to -70, from digestion by DNase I. This site(s) lies immediately upstream from the site at which sigma 54 RNA polymerase binds, is downstream of a high-affinity binding site for the transcriptional activator NRI approximately P, and partially overlaps a low-affinity NRI approximately P-binding site. Binding of Nac to the DNA resulted in bending of the DNA but did not interfere with the binding of sigma 54 RNA polymerase to the promoter or with the binding of NRI approximately P to either the high-affinity site or low-affinity site. Furthermore, transcription assays with various wild-type and mutant templates suggested that Nac did not exclude NRI approximately P from either the low- or high-affinity sites, nor did Nac interfere with the ability of the polymerase to form the open complex when the binding sites for NRI approximately P were moved to different locations upstream from the promoter. Rather, Nac seemed to repress by an antiactivation mechanism in which the interaction of the NRI approximately P, bound at its normal sites, with sigma 54 RNA polymerase, bound to the promoter, was prevented.
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PMID:Repression of the Klebsiella aerogenes nac promoter. 755 39

In Klebsiella pneumoniae, transcription of all nif (nitrogen fixation) operons except the regulatory nifLA operon itself is regulated by the proteins NifA and NifL. NifA, an enhancer-binding protein, activates transcription by RNA polymerase containing the alternative sigma factor sigma 54. The central catalytic domain of NifA is sufficient for transcriptional activation, which can occur from solution. In vivo, NifL antagonizes the action of NifA in the presence of molecular oxygen or combined nitrogen. Inhibition has also been shown in vitro, but it was not responsive to environmental signals. Assuming a two-domain structure of NifL, we localized inhibition by NifL to its carboxy (C)-terminal domain, which is more soluble than the intact protein. The first line of evidence for this is that internal deletions of NifL containing an intact C-terminal domain were able to inhibit transcriptional activation by NifA in a coupled transcription-translation system. The second line of evidence is that the isolated C-terminal domain of NifL (assayed as a fusion to the soluble maltose-binding protein [MBP]) was sufficient to inhibit transcriptional activation by the central domain of NifA in a purified transcription system. The final line of evidence is that an MBP fusion to the C-terminal domain of NifL inhibited transcriptional activation by NifA in vivo. On the basis of these data, we postulate that the inhibitory function of NifL lies in its C-terminal domain and hence infer that this domain is responsible for interaction with NifA. Gel filtration experiments with MBP-NifL fusion derivatives lacking portions of the N- or C-terminal domain of the protein revealed that the C-terminal domain is the most soluble part of NifL. Up to 50% of two MBP-NifL truncations containing only the C-terminal domain appeared to be in a defined dimeric state.
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PMID:The C-terminal domain of NifL is sufficient to inhibit NifA activity. 766 87

The upstream noncoding region of the Synechococcus sp. strain PCC 7942 (hereafter referred to as Synechococcus 7942) glnA gene was fused to the cat gene in order to study the expression of glnA both in Synechococcus 7942 and in Escherichia coli. The lack of cat expression in E. coli indicated that the glnA promoter was not recognized by E. coli RNA polymerase. The fused construct was integrated into the Synechococcus 7942 chromosome at a neutral site. Expression of the cat reporter gene was regulated under various nitrogen conditions in a way similar to that of the glnA gene. A deletion introduced at the binding site of the NtcA regulatory protein abolished derepression of the glnA promoter during growth in nitrate and under nitrogen starvation. Deletion of the sequence between the transcription and translation start sites of glnA prevented the repression observed during growth in ammonium. These results indicate that the glnA promoter is subject to complex regulation that involves sequences upstream and downstream from the transcription start site.
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PMID:Characterization of cis elements that regulate the expression of glnA in Synechococcus sp. strain PCC 7942. 772 15

The transcription of sigma 54 RNA polymerase-dependent nitrogen-regulated genes is activated by nitrogen regulator I (NRI)-phosphate. The kinase NRII is responsible for the phosphorylation of NRI. It has been shown that NRII also has the ability to dephosphorylate NRI-phosphate but only when PII is present at a concentration greatly in excess of that of NRII. We have now shown that glutamate enables PII to stimulate the dephosphorylation of NRI-phosphate when present in equimolar concentration with NRII. This effect of glutamate appears to be a backup control that becomes effective when the normal regulation of PII activity is disabled.
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PMID:Activation of the dephosphorylation of nitrogen regulator I-phosphate of Escherichia coli. 786 Jun 2

The enhancer-binding protein NIFA is required for transcriptional activation of nif promoters by the alternative holoenzyme form of RNA polymerase, which contains the sigma factor sigma 54 (sigma N). NIFA hydrolyzes nucleoside triphosphates to catalyze the isomerization of closed promoter complexes to transcriptionally competent open complexes. The activity of NIFA is antagonized by the regulatory protein NIFL in response to oxygen and fixed nitrogen in vivo. We have investigated the requirement for nucleotides in the formation and stability of open promoter complexes by NIFA and inhibition of its activity by NIFL at the Klebsiella pneumoniae nifH promoter. Open complexes formed by sigma 54-containing RNA polymerase are considerably more stable to heparin challenge in the presence of GTP than in the presence of ATP. This differential stability is most probably a consequence of GTP being the initiating nucleotide at this promoter. Adenosine nucleosides are specifically required for Azotobacter vinelandii NIFL to inhibit open complex formation by native NIFA, and the nucleoside triphosphatase activity of NIFA is strongly inhibited by NIFL under these conditions. We propose a model in which NIFL modulates the activity of NIFA via an adenosine nucleotide switch.
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PMID:Transcriptional activation of the nitrogenase promoter in vitro: adenosine nucleotides are required for inhibition of NIFA activity by NIFL. 786 90

The Bradyrhizobium japonicum NifA protein, the central regulator for nitrogen fixation gene expression, is encoded in the fixRnifA operon. This operon is activated during free-living anaerobic growth and in the symbiotic root nodule bacteroid state. In addition, it is expressed in aerobic conditions, albeit at a low level. Here, we report that this pattern of expression is due to the presence of two overlapping promoters: fixRp1, which is of the -24/-12 class recognized by the RNA polymerase sigma 54, and fixRp2, which shares homology with the -35 and -10 regions found in other putative B. japonicum housekeeping promoters. Primer extension analyses showed that fixRp1 directed the synthesis of a transcript, P1, that starts 12 nucleotides downstream of the -12 region. In addition to sigma 54, P1 was dependent on NifA and low oxygen tension. Transcripts originating from fixRp2 started at two sites: one coincided with P1, while the most abundant, P2 initiated just two nucleotides further downstream of P1. Expression from fixRp2 was dependent on the upstream -68 promoter region, a region known to bind a putative activator protein, but it was independent of sigma 54 and NifA. This promoter was expressed in aerobic and anaerobic conditions but was not expressed in 30-day-old bacteroids. Mutations in the conserved 12 region for the sigma 54 promoter did not show any transcript, because these mutations also disrupted the overlapping -10 region of the fixRp2 promoter. Conversely, mutations at the -24 region only affected the sigma 54-dependent P1 transcript, having no effect on the expression of P2. In the absence of omega(54), anaerobic expression from the fixRp(2) promoter was enhanced threefold, suggesting that in the wild-type strain, the two RNA polymerase holoenzymes must compete for binding to the same promoter region.
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PMID:Overlapping promoters for two different RNA polymerase holoenzymes control Bradyrhizobium japonicum nifA expression. 789 98

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