Rhodobacter capsulatus nifA1 promoter: high-GC -10 regions in high-GC bacteria and the basis for their transcription.
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It was previously shown that the Rhodobacter capsulatus NtrC enhancer-binding protein activates the R. capsulatus housekeeping RNA polymerase but not the Escherichia coli RNA polymerase at the nifA1 promoter. We have tested the hypothesis that this activity is due to the high G+C content of the -10 sequence. A comparative analysis of R. capsulatus and other alpha-proteobacterial promoters with known transcription start sites suggests that the G+C content of the -10 region is higher than that for E. coli. Both in vivo and in vitro results obtained with nifA1 promoters with -10 and/or -35 variations are reported here. A major conclusion of this study is that alpha-proteobacteria have evolved a promiscuous sigma factor and core RNA polymerase that can transcribe promoters with high-GC -10 regions in addition to the classic E. coli Pribnow box. To facilitate studies of R. capsulatus transcription, we cloned and overexpressed all of the RNA polymerase subunits in E. coli, and these were reconstituted in vitro to form an active, recombinant R. capsulatus RNA polymerase with properties mimicking those of the natural polymerase. Thus, no additional factors from R. capsulatus are necessary for the recognition of high-GC promoters or for activation by R. capsulatus NtrC. The addition of R. capsulatus sigma(70) to the E. coli core RNA polymerase or the use of -10 promoter mutants did not facilitate R. capsulatus NtrC activation of the nifA1 promoter by the E. coli RNA polymerase. Thus, an additional barrier to activation by R. capsulatus NtrC exists, probably a lack of the proper R. capsulatus NtrC-E. coli RNA polymerase (protein-protein) interaction(s). (+info)
Identification of critical residues in GlnB for its activation of NifA activity in the photosynthetic bacterium Rhodospirillum rubrum.
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The P(II) regulatory protein family is unusually widely distributed, being found in all three domains of life. Three P(II) homologs called GlnB, GlnK, and GlnJ have been identified in the photosynthetic bacterium Rhodospirillum rubrum. These have roles in at least four distinct functions, one of which is activation of the nitrogen fixation-specific regulatory protein NifA. The activation of NifA requires only the covalently modified (uridylylated) form of GlnB. GlnK and GlnJ are not involved. However, the basis of specificity for different P(II) homologs in different processes is poorly understood. We examined this specificity by altering GlnJ to support NifA activation. A small number of amino acid substitutions in GlnJ were important for this ability. Two (affecting residues 45 and 54) are in a loop called the T-loop, which contains the site of uridylylation and is believed to be very important for contacts with other proteins, but other critical residues lie in the C terminus (residues 95-97 and 109-112) and near the N terminus (residues 3-5 and 17). Because many of the residues important for P(II)-NifA interaction lie far from the T-loop in the known x-ray crystal structures of P(II) proteins, our results lead to the hypothesis that the T-loop of GlnB is flexible enough to come into proximity with both the C- and N-terminal regions of the protein to bind NifA. Finally, the results show that the level of P(II) accumulation is also an important factor for NifA activation. (+info)
SigC, the group 2 sigma factor of RNA polymerase, contributes to the late-stage gene expression and nitrogen promoter recognition in the cyanobacterium Synechocystis sp. strain PCC 6803.
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We examined the role of SigC (Sll0184), a sigma factor of RNA polymerase (RNAP), in a unicellular cyanobacterium, Synechocystis sp. strain PCC 6803. On the inactivation of sigC, which is an Escherichia coli rpoD homolog, cells were viable but had a low survival rate in the stationary phase of growth under normal physiological conditions, indicating that SigC is a group 2 type sigma factor. In analyses of transcript and protein levels using the sigC knockout strain, it was found that expression of glnB, a nitrogen key regulatory gene, is controlled by SigC in the stationary phase. Primer extension revealed that the glnB nitrogen promoter (P2) was specifically recognized by SigC in the stationary phase under conditions of nitrogen starvation. In vitro studies with purified enzymes indicated effective transcription, on supercoiled DNA templates, from P2 by SigC-RNAP with NtcA which is an activator for nitrogen gene transcription. DNase I footprinting also indicated binding and related sites of NtcA and/or RNAP with SigC on the nitrogen promoter. The unique promoter architecture and the mechanism of transcription by RNAP with SigC are also discussed. (+info)
Expression of cyanobacterial genes involved in heterocyst differentiation and dinitrogen fixation along a plant symbiosis development profile.
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Members of the cyanobiont genus Nostoc, forming an endosymbiosis with members of the angiosperm genus Gunnera, undergo a number of characteristic phenotypic changes during the development of the symbiosis, the genetic background of which is largely unknown. Transcription patterns of genes related to heterocyst differentiation and dinitrogen fixation and corresponding protein profiles were examined, using reverse transcription-polymerase chain reaction and Western blots, along a developmental (apex to mature parts) sequence in Gunnera magellanica and G. manicata and under mimicked symbiotic conditions in a free-living Gunnera isolate (Nostoc strain 0102). The hetR gene was highly expressed and correlated positively with an increase in heterocyst frequency and with ntcA expression, whereas nifH expression was already high close to the growing apex and glnB (P(II)) expression decreased along the symbiotic profile. Although gene expression appeared to be regulated to a large extent in the same fashion as in free-living cyanobacteria, significant differences were apparent, such as the overexpression of both hetR and ntcA and the contrasting down-regulation of glnB, features indicating important regulatory differences between symbiotic and free-living cyanobacteria. The significance of these findings is discussed in a symbiotic context. (+info)
Interactions between the nitrogen signal transduction protein PII and N-acetyl glutamate kinase in organisms that perform oxygenic photosynthesis.
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PII, one of the most conserved signal transduction proteins, is believed to be a key player in the coordination of nitrogen assimilation and carbon metabolism in bacteria, archaea, and plants. However, the identity of PII receptors remains elusive, particularly in photosynthetic organisms. Here we used yeast two-hybrid approaches to identify new PII receptors and to explore the extent of conservation of PII signaling mechanisms between eubacteria and photosynthetic eukaryotes. Screening of Synechococcus sp. strain PCC 7942 libraries with PII as bait resulted in identification of N-acetyl glutamate kinase (NAGK), a key enzyme in the biosynthesis of arginine. The integrity of Ser49, a residue conserved in PII proteins from organisms that perform oxygenic photosynthesis, appears to be essential for NAGK binding. The effect of glnB mutations on NAGK activity is consistent with positive regulation of NAGK by PII. Phylogenetic and yeast two-hybrid analyses strongly suggest that there was conservation of the NAGK-PII regulatory interaction in the evolution of cyanobacteria and chloroplasts, providing insight into the function of eukaryotic PII-like proteins. (+info)
Lack of evidence for phosphorylation of Arabidopsis thaliana PII: implications for plastid carbon and nitrogen signaling.
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The PII signal transduction protein is regulated by covalent modification in most prokaryotic organisms. In enteric bacteria PII is uridylylated on a specific tyrosine residue in the T-loop region, while in certain cyanobacteria it is phosphorylated at the serine residue two positions away from the equivalent modified tyrosine of enteric bacteria. Covalent modification functions primarily to signal cellular nitrogen status in prokaryotes. Here we have examined the phospho-status of Arabidopsis thaliana PII under various growth conditions employing a variety of techniques, including in vivo labeling, phosphospecific antibodies, protein phosphatase treatment, mass spectrometry and protein kinase assays. All results indicate that plant PII is not regulated by phosphorylation. Edman sequencing of immunoprecipitated A. thaliana PII revealed the N-terminal sequences AQISSD and QISSDY, indicating that the mature protein is cleaved from its transit peptide in vivo at the site(s) predicted by ChloroP. Western blot analysis also demonstrated that plant PII protein expression varies little with nutrient regime. (+info)
Phosphorylation-independent dimer-dimer interactions by the enhancer-binding activator NtrC of Escherichia coli: a third function for the C-terminal domain.
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The response regulator NtrC transcriptionally activates genes of the nitrogen-regulated (Ntr) response. Phosphorylation of its N-terminal receiver domain stimulates an essential oligomerization of the central domain. Deletion of the central domain reduces, but does not eliminate, intermolecular interactions as assessed by cooperative binding to DNA. To analyze the structural determinants and function of this central domain-independent as well as phosphorylation-independent oligomerization, we randomly mutagenized DNA coding for an NtrC without its central domain and isolated strains containing NtrC with defective phosphorylation-independent cooperative binding. The alterations were primarily localized to helix B of the C-terminal domain. Site-specific mutagenesis that altered surface residues of helix B confirmed this localization. The purified NtrC variants, with or without the central domain, were specifically defective in phosphorylation-independent cooperative DNA binding and had little defect, if any, on other functions, such as non-cooperative DNA binding. We propose that this region forms an oligomerization interface. Full-length NtrC variants did not efficiently repress the glnA-ntrBC operon when NtrC was not phosphorylated, which suggests that phosphorylation-independent cooperative binding sets the basal level for glutamine synthetase and the regulators of the Ntr response. The NtrC variants in these cells generally, but not always, supported wild-type growth in nitrogen-limited media and wild-type activation of a variety of Ntr genes. We discuss the differences and similarities between the NtrC C-terminal domain and the homologous Fis, which is also capable of intermolecular interactions. (+info)
Mutations altering the N-terminal receiver domain of NRI (NtrC) That prevent dephosphorylation by the NRII-PII complex in Escherichia coli.
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The phosphorylated form of NRI is the transcriptional activator of nitrogen-regulated genes in Escherichia coli. NRI approximately P displays a slow autophosphatase activity and is rapidly dephosphorylated by the complex of the NRII and PII signal transduction proteins. Here we describe the isolation of two mutations, causing the alterations DeltaD10 and K104Q in the receiver domain of NRI, that were selected as conferring resistance to dephosphorylation by the NRII-PII complex. The mutations, which alter highly conserved residues near the D54 site of phosphorylation in the NRI receiver domain, resulted in elevated expression of nitrogen-regulated genes under nitrogen-rich conditions. The altered NRI receiver domains were phosphorylated by NRII in vitro but were defective in dephosphorylation. The DeltaD10 receiver domain retained normal autophosphatase activity but was resistant to dephosphorylation by the NRII-PII complex. The K104Q receiver domain lacked both the autophosphatase activity and the ability to be dephosphorylated by the NRII-PII complex. The properties of these altered proteins are consistent with the hypothesis that the NRII-PII complex is not a true phosphatase but rather collaborates with NRI approximately P to bring about its dephosphorylation. (+info)