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

Rhizobium meliloti DctD, a sigma 54-dependent transcriptional activator, may be negatively controlled by a subdomain in the C-terminal end of its two-component receiver module

Rhizobium meliloti DctD is believed to have three functional domains: an N-terminal, two-component receiver domain; and like other sigma 54-dependent activators, C-terminal and central domains for DNA binding and transcription activation. We have characterized a progressive series of N-terminal deletions of R. meliloti DctD. The N-terminal domain was not needed for binding the dctA upstream activation sequence. Only 25% of the C-terminal end of the receive domain was needed to significantly inhibit the central domain, and proteins lacking up to 60% of the N-terminal end of the receiver domain were 'inducible' in R. meliloti cells. We hypothesize that the N-terminal two-thirds of the DctD receiver domain augments and controls an adjacent subdomain for inhibiting the central domain.

Molecular genetics of Thiobacillus ferrooxidans

Thiobacillus ferrooxidans is a gram-negative, highly acidophilic (pH 1.5 to 2.0), autotrophic bacterium that obtains its energy through the oxidation of ferrous iron or reduced inorganic sulfur compounds. It is usually dominant in the mixed bacterial populations that are used industrially for the extraction of metals such as copper and uranium from their ores. More recently, these bacterial consortia have been used for the biooxidation of refractory gold-bearing arsenopyrite ores prior to the recovery of gold by cyanidation. The commercial use of T. ferrooxidans has led to an increasing interest in the genetics and molecular biology of the bacterium. Initial investigations were aimed at determining whether the unique physiology and specialized habitat of T. ferrooxidans had been accompanied by a high degree of genetic drift from other gram-negative bacteria. Early genetic studies were comparative in nature and concerned the isolation of genes such as nifHDK, glnA, and recA, which are widespread among bacteria. From a molecular biology viewpoint, T. ferrooxidans appears to be a typical member of the proteobacteria. In most instances, cloned gene promoters and protein products have been functional in Escherichia coli. Although T. ferrooxidans has proved difficult to transform with DNA, research on indigenous plasmids and the isolation of the T. ferrooxidans merA gene have resulted in the development of a low-efficiency electroporation system for one strain of T. ferrooxidans. The most recent studies have focused on the molecular genetics of the pathways associated with nitrogen metabolism, carbon dioxide fixation, and components of the energy-producing mechanisms.

Structure and expression of the alternative sigma factor, RpoN, in Rhodobacter capsulatus; physiological relevance of an autoactivated nifU2-rpoN superoperon

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).

Oligomerization of NTRC at the glnA enhancer is required for transcriptional activation

To activate transcription of the glnA gene, the dimeric NTRC protein (nitrogen regulatory protein C) of enteric bacteria binds to an enhancer located approximately 100 bp upstream of the promoter. The enhancer is composed of two binding sites for NTRC that are three turns of the DNA helix apart. One role of the enhancer is to tether NTRC in high local concentration near the promoter to allow for its frequent interaction with sigma 54 holoenzyme by DNA looping. We have found that a second role of the enhancer is to ensure oligomerization of NTRC into a complex of at least two dimers that is required for transcriptional activation. Formation of this complex is greatly facilitated by a protein-protein interaction between NTRC dimers that is increased when the protein is phosphorylated.

The glnB region of the Escherichia coli chromosome

We present sequences of the glnB gene of Escherichia coli and of two open reading frames (ORFs) located directly upstream of glnB and transcribed in the same direction. The major transcriptional start sites for glnB are located between ORF-2 and glnB, but some transcription of glnB is initiated at the promoter for ORF-1. The putative amino acid sequence of the ORF-2 product has high homology to that of response regulators which by phosphorylation acquire the ability to activate transcription of sigma 54-dependent promoters. The product of ORF-1 showed no similarity to other known proteins. The product of neither ORF-1 nor ORF-2 is necessary for the ability of PII, the product of glnB, to bring about the repression of glutamine synthetase in response to nitrogen excess. On the other hand, the product of hmpA, a gene located on the other side of glnB and transcribed in the opposite direction, appears to play an auxiliary role in this process.

Mutational analysis of the bacterial signal-transducing protein kinase/phosphatase nitrogen regulator II (NRII or NtrB)

The signal-transducing kinase/phosphatase nitrogen regulator II (NRII or NtrB) is required for the efficient positive and negative regulation of glnA, encoding glutamine synthetase, and the Ntr regulon in response to the availability of ammonia. Alteration of highly conserved residues within the kinase/phosphatase domain of NRII revealed that the positive and negative regulatory functions of NRII could be genetically separated and that negative regulation by NRII did not require the highly conserved His-139, Glu-140, Asn-248, Asp-287, Gly-289, Gly-291, Gly-313, or Gly-315 residue. These mutations affected the positive regulatory function of NRII to various extents. Certain substitutions at codons 139 and 140 resulted in mutant NRII proteins that were transdominant negative regulators of glnA and the Ntr regulon even in the absence of nitrogen limitation. In addition, we examined three small deletions near the 3' end of the gene encoding NRII; these resulted in altered proteins that retained the negative regulatory function but were defective to various extents in the positive regulatory function. A truncated NRII protein missing the C-terminal 59 codons because of a nonsense mutation at codon 291 lacked entirely the positive regulatory function but was a negative regulator of glnA even in the absence of nitrogen limitation. Thus, we have identified both point and deletion mutations that convert NRII into a negative regulator of glnA and the Ntr regulon irrespective of the nitrogen status of the cell.

Mechanism of autophosphorylation of Escherichia coli nitrogen regulator II (NRII or NtrB): trans-phosphorylation between subunits

Nitrogen regulator II (NRII or NtrB) is a homodimeric signal-transducing protein kinase/phosphatase responsible for the transcriptional regulation of the Ntr regulon in Escherichia coli. NRII is a member of a large family of proteins that are part of the related two-component signal transduction systems. We studied the mechanism of NRII autophosphorylation by using purified components. Alteration of the site of NRII autophosphorylation to asparagine (H-139-->N [H139N]) or deletion of the C-terminal 59 amino acids of NRII (ter291) resulted in proteins that were not autophosphorylated upon incubation with ATP. Alteration of glycine 313 to alanine resulted in a protein (G313A) that was phosphorylated to a lesser extent than the wild-type protein. Unlike wild-type NRII and H139N, G313A could not be efficiently cross-linked to [alpha-32P]ATP, suggesting that the G313A mutation affects nucleotide binding. Fusion of maltose-binding protein (MBP) to the N-terminal end of NRII resulted in a protein (MBP-NRII) that autophosphorylated normally. We developed a procedure for forming mixed dimers in vitro from these proteins. In mixed dimers consisting of MBP-NRII and H139N, only the MBP-NRII subunit is phosphorylated. In contrast, in mixed dimers consisting of MBP-NRII and G313A, phosphorylation is predominantly on the G313A subunit. We also demonstrated that the G313A and H139N proteins could complement for the autophosphorylation reaction when they were treated so as to permit the formation of mixed dimers and that the wild-type and H139N proteins could phosphorylate the ter291 protein. These results indicate that the autophosphorylation reaction occurs within the dimer by a trans, intersubunit mechanism in which one subunit binds ATP and phosphorylates the other subunit.

Spatial and temporal phosphorylation of a transcriptional activator regulates pole-specific gene expression in Caulobacter

Polar localization of proteins in the Caulobacter predivisional cell results in the formation of two distinct progeny cells, a motile swarmer cell and a sessile stalked cell. The transcription of several flagellar promoters is localized to the swarmer pole of the predivisional cell. We present evidence that the product of the flbD gene is the transcriptional activator of these promoters. We show that FlbD is distributed in all cell types and in both poles of the predivisional cell. We also demonstrate that FlbD can be phosphorylated, and that a FlbD kinase activity is under cell cycle control. Cells expressing a FlbD mutant that should activate transcription in the absence of phosphorylation, exhibited an alteration in the temporal pattern of flagellin transcription. Furthermore, predivisional cells expressing the mutant FlbD failed to polarly localize flagellin synthesis. We propose that the phosphorylation of FlbD is restricted to the swarmer compartment of the predivisional cell, and serves as the control point for regulating the spatial transcription of flagellar promoters.

The genes of the glutamine synthetase adenylylation cascade are not regulated by nitrogen in Escherichia coli

Regulation of glutamine-synthetase (GS) activity in enteric bacteria involves a complex cascade of events. In response to nitrogen limitation, a transferase catalyses the uridylylation of the PII protein, which in turn stimulates deadenylylation of GS. Deadenylylated GS is the more active form of the enzyme. Here we characterize in detail the genes from Escherichia coli encoding uridylyl-transferase (glnD), the PII protein (glnB), and adenylyl-transferase (glnE). glnD is transcribed from its own promoter, glnE is contranscribed with another gene, orfXE, whereas glnB is partly contranscribed with a gene encoding a homologue of the transcription activator NtrC. All three gln regulatory genes were constitutively expressed at a low level, i.e. their expression was independent of the nitrogen status and the RNA polymerase sigma factor sigma 54. We conclude that the functioning of the GS adenylylation cascade is regulated by modulation of the activities of uridylyl-transferase and adenylyl-transferase, rather than by changes in the expression of their genes.

Erwinia stewartii WtsA, a positive regulator of pathogenicity gene expression, is similar to Pseudomonas syringae pv. phaseolicola HrpS

Erwinia stewartii contains a large cluster of wts genes that are required by this bacterium for pathogenicity on corn plants. Three complementation groups within the right half of this cluster, wtsA, wtsC, and wtsB, were previously identified. In this study, WtsA was found to be a positive activator of wtsB::lacZ expression. The wtsA locus was sequenced and a single open reading frame is present within the wtsA locus, which has the capacity to encode a 323 amino acid polypeptide. A corresponding 38 kDa protein was observed in Escherichia coli minicells containing the cloned wtsA gene. The predicted WtsA polypeptide has significant similarity to HrpS from Pseudomonas syringae pv. phaseolicola, as well as other members of the NtrC class of prokaryotic regulatory proteins. Similar to other genes activated by NtrC regulators, wtsB::lacZ expression in E. coli was dependent upon rpoN.

Prokaryotic enhancer-binding proteins reflect eukaryote-like modularity: the puzzle of nitrogen regulatory protein C

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Phosphorylation and nucleotide-dependent dephosphorylation of hepatic polypeptides related to the plasma cell differentiation antigen PC-1

A glycoprotein fraction was isolated from rat liver membranes by affinity chromatography on immobilized wheat-germ lectin. Incubation of this fraction with MgATP or MgGTP resulted in a sequential phosphorylation and dephosphorylation of a complex of three polypeptides (118, 128 and 197 kDa on SDS/PAGE) with N-linked sialyloligosaccharides. Each polypeptide was recognized by polyclonal antibodies against recombinant plasma cell differentiation antigen PC-1. The relationship of the 118 kDa and 128 kDa polypeptides with PC-1 was confirmed by observations that they are linked by disulphide bonds into a larger protein, and that they are exclusively phosphorylated on Thr residues. Phosphorylation of p118, p128 and p197 only occurred after a lag period (up to 90 min at 30 degrees C), which lasted until most of the ATP had been converted to adenosine and Pi, with ADP and AMP as intermediate products. The length of the latency period increased with the concentration of initially added ATP (5-1000 microM) and could be prolonged by a second addition of similar concentrations of ATP, ADP, AMP and various nucleotide analogues. Most potent were the alpha beta-methylene derivatives of ADP and ATP. Adenosine was poorly effective. AMP, ADP, and perhaps ATP, emerge as the direct determinants of the latency. After further purification of the lectin-purified membrane fraction on anion-exchange and molecular-sieve columns, the complex of p118, p128 and p197 was still capable of autophosphorylation and dephosphorylation. The dephosphorylation was not affected by classical inhibitors (NaF, okadaic acid, EDTA, EGTA, phenylalanine). It was stimulated about 20-fold by various adenine nucleotides and analogues, with the same order of efficiency as noted for the induction of the latency. A similar stimulation of dephosphorylation was caused by 0.5 mM Na3VO4, which also prevented the phosphorylation of the three polypeptides. The likely explanation for the latency that precedes the phosphorylation of the membrane proteins is that the action of a protein kinase is initially offset by nucleotide-stimulated dephosphorylation.

Sequence, genetic, and lacZ fusion analyses of a nifR3-ntrB-ntrC operon in Rhodobacter capsulatus

Transcription of Rhodobacter capsulatus genes encoding the nitrogenase polypeptides (nifHDK) is repressed by fixed nitrogen and oxygen. Regulatory genes required to sense and relay the nitrogen status of the cell are glnB, ntrB (nifR2), and ntrC (nifR1). R. capsulatus nifA1 and nifA2 require ntrC for activation when fixed nitrogen is limiting. The polypeptides encoded by nifA1 and nifA2 along with the alternate sigma factor RpoN activate nifHDK and the remaining nif genes in the absence of both fixed nitrogen and oxygen. In this study we report the sequence and genetic analysis of the previously identified nifR3-ntrB-ntrC regulatory locus. nifR3 is predicted to encode a 324-amino-acid protein with significant homology to an upstream open reading frame cotranscribed with the Escherichia coli regulatory gene, fis. Analysis of ntrC-lacZ fusions and complementation data indicate that nifR3 ntrBC constitute a single operon. nifR3-lacZ fusions are expressed only when lacZ is in the proper reading frame with the predicted nifR3 gene product. Tn5, a kanamycin-resistance cassette, and miniMu insertions in nifR3 are polar on ntrBC (required for nif transcription). This gene organization suggests that the nifR3 gene product may be involved in nitrogen regulation, although nifR3 is not stringently required for nitrogen fixation when ntrBC are present on a multicopy plasmid. In addition, a R. capsulatus strain with a 22-nucleotide insert in the chromosomal nifR3 gene was constructed. This nifR3 strain is able to fix nitrogen and activate nifA1 and nifA2 genes, again supporting the hypothesis that nifR3 is not stringently required for ntrC-dependent gene activation in R. capsulatus.

Alterations of highly conserved residues in the regulatory domain of nitrogen regulator I (NtrC) of Escherichia coli

Transcription of many nitrogen-regulated (Ntr) genes requires the phosphorylated form of nitrogen regulator I (NRI, or NtrC), which binds to sites that are analogous to eukaryotic enhancers. A highly conserved regulatory domain contains the site of phosphorylation and controls the function of NRI. We analyzed the effects of substitutions in highly conserved residues that are part of the active site of phosphorylation of NRI in Escherichia coli. Fourteen substitutions of aspartate 54, the site of phosphorylation, impaired the response to nitrogen deprivation. Only one of these variants, NRI D-54-->E (NRI-D54E), could significantly stimulate transcription from glnAp2, the major promoter of the glnALG operon. Cells with this variant grew with arginine as a nitrogen source. Experiments with purified components showed that unphosphorylated NRI-D54E stimulated transcription. In contrast, substitutions at aspartate 11 were not as deleterious as those at aspartate 54. Finally, we showed that NRI-K103R, in which arginine replaces the absolutely conserved lysine, is functionally active and efficiently phosphorylated. This substitution appears to stabilize the phosphoaspartate of NRI. The differences between our results and those from study of homologous proteins suggest that there may be significant differences in the way highly conserved residues participate in the transition to the activated state.

Computer simulation of the phosphorylation cascade controlling bacterial chemotaxis

We have developed a computer program that simulates the intracellular reactions mediating the rapid (nonadaptive) chemotactic response of Escherichia coli bacteria to the attractant aspartate and the repellent Ni2+ ions. The model is built from modular units representing the molecular components involved, which are each assigned a known value of intracellular concentration and enzymatic rate constant wherever possible. The components are linked into a network of coupled biochemical reactions based on a compilation of widely accepted mechanisms but incorporating several novel features. The computer motor shows the same pattern of runs, tumbles and pauses seen in actual bacteria and responds in the same way as living bacteria to sudden changes in concentration of aspartate or Ni2+. The simulated network accurately reproduces the phenotype of more than 30 mutants in which components of the chemotactic pathway are deleted and/or expressed in excess amounts and shows a rapidity of response to a step change in aspartate concentration similar to living bacteria. Discrepancies between the simulation and real bacteria in the phenotype of certain mutants and in the gain of the chemotactic response to aspartate suggest the existence of additional as yet unidentified interactions in the in vivo signal processing pathway.

Oxygen regulation of nifA transcription in vitro

In Rhizobium meliloti, transcription of the key nitrogen-fixation regulatory genes nifA and fixK is induced in response to microaerobiosis through the action of the FixL and FixJ proteins. These two proteins are sensor and regulator homologues, respectively, of a large family of bacterial two-component systems involved in sensing and responding to environmental changes. A soluble, truncated form of the membrane protein FixL, FixL*, has been shown to be a hemoprotein that phosphorylates and dephosphorylates FixJ in response to oxygen tension. Here we use an in vitro transcription system to prove that FixJ is a transcriptional activator of both nifA and fixK and that phosphorylation of FixJ markedly increases its activity. Phosphorylation was achieved either by preincubating FixJ with FixL* and ATP or by exposing FixJ to the inorganic phospho donor ammonium hydrogen phosphoramidate. Both FixJ and FixJ-phosphate formed heparin-resistant complexes under the assay conditions used. Lastly, we were able to show that anaerobiosis, in the presence of FixL* and ATP, greatly stimulates FixJ activity at the nifA promoter with either Escherichia coli or R. meliloti RNA polymerase. This use of atmospheric oxygen to control nifA transcription in vitro represents a reconstitution of a bacterial two-component signal transduction system in its entirety, from effector to ultimate target, by the use of purified components.

Identification of a nitrogen-regulated promoter controlling expression of Klebsiella pneumoniae urease genes

Synthesis of urease by Klebsiella species is known to be induced when the nitrogen source of the growth medium is limiting, suggesting that urease gene expression is controlled by the nitrogen regulatory (ntr) system. This study showed that K. pneumoniae with mutations in either ntrA or ntrC, two integral components of the ntr system, were phenotypically urease-negative. These mutants could be complemented back to a urease positive phenotype with recombinant plasmids encoding the corresponding ntr gene. A series of ure-lacZYA transcriptional fusions, in conjunction with primer extension analysis, identified a DNA region that encoded a nitrogen-regulated promoter. This promoter region controlled transcription of ureD, the first gene in the Klebsiella pneumoniae urease gene cluster, and ureA, a gene that resides immediately downstream of ureD. A high level of transcription from the ureD promoter required NAC, a recently characterized member of the nitrogen regulatory cascade. NAC is a Lys R-like transcriptional regulator that can act at sigma 70 promoters; expression from nac itself is dependent upon NTRA. Therefore, expression of K. pneumoniae urease was dependent upon the nitrogen regulatory cascade, and transcription of at least two urease genes was from a promoter that was positively regulated by NAC.

Signal transduction and sporulation in Bacillus subtilis: autophosphorylation of Spo0A, a sporulation initiation gene product

Spo0A is a positive/negative transcriptional regulator that plays a very important role in sporulation initiation in Bacillus subtilis. The N-terminal amino acid sequence of Spo0A is homologous to that of regulator proteins of the two-component regulatory systems involved in signal transduction in bacteria. Phosphorylation of SpooA through a phosphorelay has been reported recently. In this study, we found that Spo0A is autophosphorylated in the presence of ATP and that an autophosphorylation-deficient Spo0A mutant is completely defective in initiating sporulation. These results suggest that Spo0A autophosphorylation is an essential event in the signal transduction process that controls sporulation in B. subtilis.

Signal transduction and virulence regulation in human and animal pathogens

Pathogens have developed many strategies for survival in animals and humans which possess very effective defense mechanisms. Although there are many different ways, in which pathogenic bacteria solved the problem to overcome the host defense, some common features of virulence mechanisms can be detected even in phylogenetically very distant bacteria (Finlay and Falkow (1989) Microb. Rev. 6, 1375-1383). One important feature is that the regulation of expression of virulence factors and the exact timing of their expression is very important for many of the pathogenic bacteria, as most of them have to encounter different growth situations during an infection cycle, which require a fast adaptation to the new situation by the expression of different factors. This review gives an overview about the mechanisms used by pathogenic bacteria to accomplish the difficult task of regulation of their virulence potential in response to environmental changes. In addition, the relationship of these virulence regulatory systems with other signal transduction mechanisms not involved in pathogenicity is discussed.

The C terminus of the alpha subunit of RNA polymerase is not essential for transcriptional activation of sigma 54 holoenzyme

Several activators of sigma 70 holoenzyme whose binding sites lie upstream of the -35 region of promoters require the C-terminal region of the alpha subunit of RNA polymerase to activate transcription. (These are among class I activators, which require the C-terminal region of the alpha subunit for transcription activation.) Because transcription by sigma 54 holoenzyme universally depends upon activators whose binding sites lie well upstream (or downstream) of promoters, we determined whether the C-terminal region of the alpha subunit was also required for transcription from the sigma 54-dependent promoter for the glnA operon. Nitrogen regulatory protein C-dependent activation from the glnA promoter remained good when RNA polymerases containing C-terminal truncations of the alpha subunit were employed. This was also the case for nitrogen fixation protein A-dependent activation if a nitrogen fixation protein A-binding site was appropriately placed upstream of the glnA promoter. These results lead to the working hypothesis (as yet untested) that activators of sigma 54 holoenzyme, which appear to make direct physical contact with the polymerase to catalyze a change in its conformation, activate the sigma 54 holoenzyme by contacting the sigma subunit rather than the alpha subunit of the core enzyme.

Effects of insertions and deletions in glnG (ntrC) of Escherichia coli on nitrogen regulator I-dependent DNA binding and transcriptional activation

Phosphorylated nitrogen regulator I (NRI, also called NTRC), encoded by glnG (ntrC), stimulates transcription in Escherichia coli and other enteric bacteria from sites analogous to eukaryotic enhancers. We isolated 30 mutants, obtained without phenotypic selection, that have either a small insertion or deletion within glnG. Mutants were classified by the ability of NRI to repress the glnAp1 and glnL promoters and to activate two versions of the nitrogen-regulated glnAp2 promoter; each activity was measured in cells grown with three concentrations of NRI. The results were interpreted within the framework of the three-domain hypothesis of NRI structure. NRI is thought to contain a phosphorylated regulatory domain that controls binding of ATP, a central domain that hydrolyzes ATP and interacts with RNA polymerase, and a DNA-binding region of unknown extent. Our results suggest that the 70 amino acids from residue 400 to the carboxyl terminus constitute a DNA-binding domain that includes residues for specific contacts and dimerization. Our results also suggest that (i) transcription from glnAp2 without specific NRI-binding sites requires binding to sites with some similarity to the specific sites, and (ii) if an NRI variant can stimulate transcription, then increasing the concentration of NRI diminishes glnA expression for all mutants but one.

Tandem DctD-binding sites of the Rhizobium meliloti dctA upstream activating sequence are essential for optimal function despite a 50- to 100-fold difference in affinity for DctD

The Rhizobium meliloti genes dctB and dctD positively regulate the expression of dctA, which encodes a C4-dicarboxylate transport protein. Here we characterize an element (UAS) located upstream of dctA that has tandem binding sites for the dctD gene product (DctD). At relatively low concentrations of active DctD, the element activated dctA transcription, but at relatively high concentrations of DctD it was inhibitory. The UAS failed to function when placed further upstream of dctA. Both DctD-binding sites were required for optimal UAS function, despite a 50- to 100-fold difference in binding affinities. Moving the promoter distal binding site 5 bp further upstream was functionally equivalent to its deletion. Based on these data, we hypothesize that the sigma 54-dependent activator DctD binds co-operatively to the R. meliloti dctA UAS, and that occupancy of both sites is required for maximal activation of dctA.

Stabilization of phosphorylated Bacillus subtilis DegU by DegR

The production of Bacillus subtilis extracellular proteases is under positive and negative regulation. The functional role of degR, one of the positive regulators, was studied in relation to the degS and degU gene products, which belong to the bacterial two-component regulatory system. Studies with a translational fusion between the Escherichia coli lacZ and the Bacillus subtilis subtilisin (aprE) genes indicated that the stimulatory site of DegR lay upstream of position -140, with the region upstream of position -200 being the major target. It was also found that degS and degU were epistatic to degR. These results suggested some relationship among the degR, degS, and degU gene products. The DegR protein was purified to homogeneity, and its in vitro effect on the phosphorylation reaction involving DegS and DegU was studied. For this purpose, a soluble-extract system in which the formation and dephosphorylation of DegU-phosphate could be examined was devised. The addition of DegR to the soluble-extract system enhanced the formation of DegU-phosphate. The enhancing effect was found to be due to the protection of DegU-phosphate from dephosphorylation. From these results, it was concluded that the positive effect of DegR on the production of the extracellular proteases is brought about by the stabilization of DegU-phosphate, which in turn may result in the stimulation of transcription of the exoprotease genes.

Signal transduction by phytochrome: phytochromes have a module related to the transmitter modules of bacterial sensor proteins

A C-terminal section of phytochromes turned out to share sequence homologies with the full length of the transmitter modules (about 250 amino acids) of bacterial sensor proteins. Coinciding hydrophobic clusters within the homologous domains imply that the overall folding of the two different types of peptides is similar. Hence, phytochromes appear to possess the structural prerequisites to transmit signals in a way bacterial sensor proteins do. The bacterial sensor proteins are known to be environmental stimuli-regulated kinases belonging to two-component systems. After sensing a stimulus by the N-terminal part of the sensor protein, conformational alterations confer the signal to its (mostly) C-terminal transmitter module which in turn is transitionally autophosphorylated at a conserved histidine. From the histidine the phosphate is transferred to the receiver module of a system-specific regulator protein which eventually acts on transcription or enzyme activity. The histidine is not conserved in phytochromes. Instead, a conserved tyrosine is found spatially very close to the histidine position. This tyrosine might play the role of histidine, and kinase function might be associated with this part of phytochrome. In spite of this divergence, the structural similarities point to a common evolutionary origin of the phytochrome and bacterial modules.

Role of phosphorylated metabolic intermediates in the regulation of glutamine synthetase synthesis in Escherichia coli

Transcription of the Ntr regulon is controlled by the two-component system consisting of the response regulator NRI (NtrC) and the kinase/phosphatase NRII (NtrB), which both phosphorylates and dephosphorylates NRI. Even though in vitro transcription from nitrogen-regulated promoters requires phosphorylated NRI, NRII-independent activation of NRI also occurs in vivo. We show here that this activation likely involves acetyl phosphate; it is eliminated by mutations that reduce synthesis of acetyl phosphate and is elevated by a mutation expected to cause accumulation of acetyl phosphate. With purified components, we investigated the mechanism by which acetyl phosphate stimulates glutamine synthetase synthesis. Acetyl phosphate, carbamyl phosphate, and phosphoramidate but not ATP or phosphoenolpyruvate acted as substrates for the autophosphorylation of NRI in vitro. Phosphorylated NRI produced by this mechanism exhibited the properties associated with NRI phosphorylated by NRII, including the activated ATPase activity of the central domain of NRI and the ability to activate transcription from the nitrogen-regulated glutamine synthetase glnAp2 promoter.

Modular structure of the FixL protein of Rhizobium meliloti

FixL protein of Rhizobium meliloti is a haemo-protein kinase which activates the transcription of nifA and fixK genes via the transcriptional activator protein FixJ under microaerobic conditions. FixL and FixJ proteins belong to the family of two-component regulatory systems for which primary sequence data predicts a modular structure. We showed, using Escherichia coli as heterologous host, that FixL indeed has a modular structure. The amino-terminal hydrophobic domain is dispensable for the oxygen-regulated activity of FixL in vivo. The central cytoplasmic non-conserved domain is necessary for the oxygen-sensing function of FixL whereas it is not necessary for the activation of FixJ by FixL. We propose that, under aerobic conditions, the central domain represses the activating function associated with the carboxy-terminal conserved domain.

gltF, a member of the gltBDF operon of Escherichia coli, is involved in nitrogen-regulated gene expression

We report here the construction and analysis of insertional mutations in each of the three genes of the gltBDF operon and the nucleotide sequence of the region downstream from gltD. Two open reading frames were identified, the first of which corresponds to gltF. The gltB and gltD genes code for the large and small subunits, respectively, of the enzyme glutamate synthase (GOGAT). gltF codes for a protein, with a molecular mass of 26,350 Da, which is required for Ntr induction. Histidase synthesis was determined as a measure of Ntr function. First, insertions in gltB, gltD or gltF all prevent Ntr induction. Second, complementation analysis indicates that high-level expression of both the gltD and gltF genes is required for the induction of the Ntr enzymes under nitrogen-limiting conditions, indicating that the phenotype of the gltB insertion probably results from polarity on gltD and gltF. Third, glutamate-dependent repression of the glt operon appears to be mediated by the product of the gltF gene. Thus, the gltBDF operon of Escherichia coli is involved in induction of the so-called Ntr enzymes in response to nitrogen deprivation, as well as in glutamate biosynthesis.

Purification and phosphorylation of the Arc regulatory components of Escherichia coli

In Escherichia coli, a two-component signal transduction system, consisting of the transmembrane sensor protein ArcB and its cognate cytoplasmic regulatory protein ArcA, controls the expression of genes encoding enzymes involved in aerobic respiration. ArcB belongs to a subclass of sensors that have not only a conserved histidine-containing transmitter domain but also a conserved aspartate-containing receiver domain of the regulator family. 'ArcB (a genetically truncated ArcB missing the two transmembrane segments on the N-terminal end) and ArcA were purified from overproducing cells. Autophosphorylation of 'ArcB was revealed when the protein was incubated with [gamma-32P]ATP but not with [alpha-32P]ATP or [gamma-32P]GTP. When ArcA was incubated in the presence of 'ArcB and [gamma-32P]ATP, ArcA acquired radioactivity at the expense of the phosphorylated protein 'ArcB-32P. When a limited amount of 'ArcB was incubated with excess ArcA and [gamma-32P]ATP, ArcA-32P increased linearly with time. Under such conditions, for a given time period the amount of ArcA phosphorylated was proportional to the concentration of 'ArcB. Thus, 'ArcB acted as a kinase for ArcA. Chemical stabilities of the phosphorylated proteins suggested that 'ArcB-32P contained both a histidyl phosphate and an aspartyl phosphate(s) and that ArcA-32P contained only an aspartyl phosphate(s).

Characterization of Escherichia coli glnL mutations affecting nitrogen regulation

Nitrogen regulator II (NRII), the product of the Escherichia coli glnL (ntrB) gene, regulates the activation of transcription of glnA and the Ntr regulon by catalyzing the phosphorylation and dephosphorylation of the transcription factor NRI. Previous results have indicated that under conditions of nitrogen excess, transcriptional activation is prevented by an NRI-phosphate phosphatase activity that is observed when NRII and another signal transduction protein known as PII (the glnB product) interact. The availability of PII for this interaction is controlled by a uridylytransferase/uridylyl-removing enzyme, encoded by glnD, that reversibly modifies PII in response to intracellular signals of nitrogen availability. Here we describe the isolation and characterization of missense mutations in glnL that suppress the Ntr- phenotype resulting from a leaky glnD mutation. The regulation of glnA expression in the pseudorevertants was found to vary from complete insensitivity to ammonia in some strains (GlnC phenotype) to nearly normal regulation by ammonia in other strains. Sequence analysis indicated that in 16 instances suppression was due to point mutations at 14 different sites; 10 different mutations resulting in a variety of phenotypes were identified in a cluster extending from codons 111 to 154 flanking the site of NRII autophosphorylation at His-139. Complementation experiments with multicopy plasmids encoding NRII or PII showed that suppression by GlnC glnL alleles was eliminated upon introduction of the plasmid encoding NRII but was not affected by introduction of the plasmid encoding PII. Conversely, suppression by certain glnL alleles that resulted in regulated expression of glnA was eliminated upon introduction of either the plasmid encoding NRII or that encoding PII. We hypothesize that mutants of the latter type result in a subtle perturbation of the NRII-PII interaction and suggest two possible mechanisms for their effects.

Phosphorylation site of NtrC, a protein phosphatase whose covalent intermediate activates transcription

The NtrC transcription factor is a member of a family of homologous prokaryotic regulatory proteins that participate in the transduction of extracellular and nutritional signals. It has been demonstrated that the phosphate group from a histidine residue of the phosphorylated NtrB protein autokinase is transferred to the NtrC protein. Phosphorylation of the NtrC protein is transient and activates its transcriptional enhancement activity. We have investigated the site of phosphorylation of the Salmonella typhimurium NtrC protein and find that it is an aspartate residue (Asp-54) that is found within a sequence conserved in all of the members of the family of regulatory proteins. We propose that this phosphorylation is an NtrC protein histidine phosphatase catalytic intermediate. This conclusion suggests that the NtrC family should be viewed not as kinase substrates but as enzymes that can catalyze the hydrolysis of their activated forms in a concentration-independent fashion. They are similar in this sense to eukaryotic signal-transducing GTPases.

Phosphorylation of nitrogen regulator I of Escherichia coli induces strong cooperative binding to DNA essential for activation of transcription

We studied the effect of phosphorylation of nitrogen regulator I (NRI) on its binding properties. Both phosphorylated and unphosphorylated NRI bind linearly to a single binding site but cooperatively to two adjacent binding sites. Cooperative binding of NRI is severely affected by phosphorylation: half-maximal binding of NRI-phosphate is at 20-fold lower concentrations than that of unphosphorylated NRI. This is more due to a huge increase in the cooperativity constant--which is the strength of interaction between two NRI dimers--than to an increase in the microscopic binding constant which is the binding affinity to a single binding site. In vitro transcription and DNA footprinting experiments showed that occupation of a single binding site by NRI is not enough for efficient activation and that activation only occurs at a higher NRI concentration. We propose an activation mechanism for NRI in which the phosphorylation of NRI induces a conformational change in the N-terminal domains of the NRI-phosphate dimers, which now interact strongly with each other, leading to a tetramerization of NRI upon binding to two adjacent binding sites. We propose that not the phosphorylation of NRI itself but rather the tetramerization of NRI-phosphate on DNA binding induces the conformational change of the central domain to the active conformation.

Mutational analysis of signal transduction by ArcB, a membrane sensor protein responsible for anaerobic repression of operons involved in the central aerobic pathways in Escherichia coli

In Escherichia coli, the expression of a group of operons involved in aerobic metabolism is regulated by a two-component signal transduction system in which the arcB gene specifies the membrane sensor protein and the arcA gene specifies the cytoplasmic regulator protein. ArcB is a large protein belonging to a subclass of sensors that have both a transmitter domain (on the N-terminal side) and a receiver domain (on the C-terminal side). In this study, we explored the essential structural features of ArcB by using mutant analysis. The conserved His-292 in the transmitter domain is indispensable, indicating that this residue is the autophosphorylation site, as shown for other homologous sensor proteins. Compression of the range of respiratory control resulting from deletion of the receiver domain and the importance of the conserved Asp-533 and Asp-576 therein suggest that the domain has a kinetic regulatory role in ArcB. There is no evidence that the receiver domain enhances the specificity of signal transduction by ArcB. The defective phenotype of all arcB mutants was corrected by the presence of the wild-type gene. We also showed that the expression of the gene itself is not under respiratory regulation.

Mutational analysis reveals functional similarity between NARX, a nitrate sensor in Escherichia coli K-12, and the methyl-accepting chemotaxis proteins

During anaerobic growth, nitrate induces synthesis of the anaerobic respiratory enzymes formate dehydrogenase-N and nitrate reductase. This induction is mediated by a transcription activator, the narL gene product. The narX gene product may be involved in sensing nitrate and phosphorylating NARL. We isolated narX mutants, designated narX*, that caused nitrate-independent expression of the formate dehydrogenase-N and nitrate reductase structural genes. We used lambda narX specialized transducing phage to genetically analyze these lesions in single copy. Two previously isolated narX* mutations, narX32 and narX71, were also constructed by site-specific mutagenesis. We found that each of these alleles caused nitrate-independent synthesis of formate dehydrogenase-N and nitrate reductase, and each was recessive to narX+. The narX* mutations lie in a region of similarity with the methyl-accepting chemotaxis protein Tsr. We suggest that the narX* proteins have lost a transmembrane signalling function such that phosphoprotein phosphatase activity is reduced relative to protein kinase activity.

The FixL protein of Rhizobium meliloti can be separated into a heme-binding oxygen-sensing domain and a functional C-terminal kinase domain

Transcription of nitrogen fixation (nif and fix) genes in Rhizobium meliloti is induced by a decrease in oxygen concentration. The products of two genes, fixL and fixJ, are responsible for sensing and transmitting the low-oxygen signal. The proteins encoded by fixL and fixJ (FixL and FixJ, respectively) are homologous to a family of bacterial proteins that transduce environmental signals through a common phosphotransfer mechanism [David, M., Daveran, M., Batut, J., Dedieu, A., Domergue, O., Ghai, J., Hertig, C., Boistard, P. & Khan, D. (1988) Cell 54, 671-683]. FixL, the oxygen sensor, is a membrane protein. It has previously been shown that a soluble derivative of FixL, FixL*, is an oxygen-binding hemoprotein and a kinase that autophosphorylates and also phosphorylates FixJ [Gilles-Gonzalez, M. A., Ditta, G. S. & Helinski, D. R. (1991) Nature (London) 350, 170-172]. In this work, deletion derivatives of fixL* were constructed and overexpressed in Escherichia coli, and the truncated proteins were purified. We show that a fragment of FixL from amino acid residue 127 to residue 260 binds heme, retains the ability to bind oxygen, and has no detectable kinase activity. A C-terminal fragment of FixL, beginning at residue 260, fails to bind heme but is active as a kinase. We also demonstrate that anaerobiosis results in an enhancement of FixL* autophosphorylation and FixJ phosphorylation activities in vitro. Finally, we show that the heme-binding region of FixL is required in vitro for oxygen regulation of its kinase activities.

Analysis of the promoters and upstream sequences of nifA1 and nifA2 in Rhodobacter capsulatus; activation requires ntrC but not rpoN

Transcription of Rhodobacter capsulatus genes encoding the nitrogenase polypeptides (nifHDK) is repressed by fixed nitrogen and oxygen. R. capsulatus nifA1 and nifA2 encode identical NIFA proteins that activate transcription of nifHDK and other nif genes. In this study, we report that nifA1-lacZ and nifA2-lacZ fusions are repressed in the presence of NH3 and activated to similar levels under nitrogen-deficient conditions. This nitrogen-controlled activation was dependent on R. capsulatus ntrC (which encodes a transcriptional activator) but not rpoN (which encodes an RNA polymerase sigma factor). We have used primer extension analyses of nifA1, nifA2 and nifH and deletion analyses of nifA1 and nifA2 upstream regions to define likely promoters and cis upstream activation sequences required for nitrogen control of these genes. Primer extension mapping confirmed that ntrC but not rpoN is required for nifA1 and nifA2 activation, and that nifA1 and nifA2 do not possess typical RPON-activated promoters.

Mapping and characterization of the promoter elements of the regulatory nif genes rpoN, nifA1 and nifA2 in Rhodobacter capsulatus

The promoter elements responsible for the expression of the regulatory nif genes rpoN, nifA1 and nifA2 of Rhodobacter capsulatus were mapped by exonuclease-III-mediated deletions and by primer extension analysis. The rpoN promoter maps 600 bp upstream of rpoN and has the characteristic features of a -24/-12 promoter. The upstream activator sequence (UAS) displays two mismatches with the NIFA consensus sequence and is located 37 bp upstream of a perfect -24/-12 promoter element. The spacing and/or the helical phasing of these two promotor elements was found to be important for promoter function. In addition, an UAS half-site may contribute to optimal promoter function. The rpoN UAS can partially substitute for the UAS of the nifE promoter. An open reading frame with homology to Klebsiella pneumoniae NIFU was identified between the rpoN promoter and rpoN and termed nifU2 since another nifU-like gene (nifU1) is located in a conventional nifUSVW operon in nif region A. Thus, rpoN, encoding an alternative sigma factor for RNA polymerase, is cotranscribed with a nifU analogous gene from an rpoN-dependent promoter. Mapping of the promoter elements involved in the expression of nifA copy 1 and copy 2 identified a novel promoter type. A conserved distal promoter element is likely to represent the binding site of NTRC in R. capsulatus. The DNA region preceding the mapped 5' ends of the nifA transcripts displays much less homology. The distance between the distal and proximal elements is about 100 bp.

Role of nitrogen regulator I (NtrC), the transcriptional activator of glnA in enteric bacteria, in reducing expression of glnA during nitrogen-limited growth

During nitrogen-limited growth, transcription of glnA, which codes for glutamine synthetase, requires sigma 54-RNA polymerase and the phosphorylated from the nitrogen regulator I (NRI; also called NtrC). In cells in which the lac promoter controlled expression of the gene coding for NRI, increasing the intracellular concentration of NRI lowered the level of glutamine synthetase. The reduction in glutamine synthetase does not appear to result from the NRI-dependent sequestering of any protein that affects transcription of glnA. Our results also suggest that the negative effect of a high concentration of NRI on glnA expression is a major determinant of the level of glutamine synthetase activity in nitrogen-limited cells of a wild-type strain. We propose that the inhibition results from an impairment of the interaction between NRI-phosphate and RNA polymerase that stimulates glnA transcription. We discuss a model that can account for this reduction in glutamine synthetase.

The product of the nitrogen fixation regulatory gene nfrX of Azotobacter vinelandii is functionally and structurally homologous to the uridylyltransferase encoded by glnD in enteric bacteria

We sequenced the nitrogen fixation regulatory gene nfrX from Azotobacter vinelandii, mutations in which cause a Nif- phenotype, and found that it encodes a 105-kDa protein (NfrX), the N terminus of which is highly homologous to that of the uridylyltransferase-uridylyl-removing enzyme encoded by glnD in Escherichia coli. In vivo complementation experiments demonstrate that the glnD and nfrX products are functionally interchangeable. A vinelandii nfrX thus appears to encode a uridylyltransferase-uridylyl-removing enzyme, and in this paper we report the first sequence of such a protein. The Nif- phenotype of nfrX mutants can be suppressed by a second mutation in a recently identified nifL-like gene immediately upstream of nifA in A. vinelandii. NifL mediates nif regulation in response to the N status in A. vinelandii, presumably by inhibiting NifA activator function as occurs in Klebsiella pneumoniae; thus, one role of NfrX is to modify, either directly or indirectly, the activity of the nifL product.

Role of multiple environmental stimuli in control of transcription from a nitrogen-regulated promoter in Escherichia coli with weak or no activator-binding sites

Nitrogen regulator I (NRI [or NtrC])-phosphate stimulates transcription from the glnAp2 promoter of the glnALG operon in enteric bacteria. Unlike most activators, NRI-phosphate can stimulate transcription without apparent activator binding sites. We observed that when lacZ was controlled by a minimal glnAp2 promoter (without NRI binding sites) in Escherichia coli, lacZ expression was regulated by two different stimuli, the nitrogen status of the medium and the particular amino acid used as a nitrogen source. The latter stimulus did not affect the activity of the wild-type glnAp2 promoter, which has two high-affinity NRI binding sites. We present several lines of evidence that suggest that the concentration of NRI-phosphate limits the activity of the minimal glnAp2 promoter in vivo. Our results also suggest that nitrogen regulator II-dependent phosphorylation of NRI cannot account for the proposed variations in the concentration of NRI-phosphate. Therefore, to account for the regulation of the minimal glnAp2 promoter by two environmental stimuli, we propose that at least two protein kinases phosphorylate NRI during nitrogen-limited growth. We isolated and characterized mutants in which NRI could not stimulate transcription from the minimal glnAp2 promoter but could activate transcription from the wild-type glnAp2 promoter. These mutants could not utilize arginine or proline as a nitrogen source, suggesting that degradation of some nitrogen sources may require transcription from promoters similar to the minimal glnAp2 promoter.

In vitro activity of the nitrogen fixation regulatory protein FIXJ from Rhizobium meliloti

Cell extracts of an Escherichia coli strain that overproduces the regulatory protein FIXJ from Rhizobium meliloti promoted transcription of fixK, a known FIXJ-dependent gene, in a coupled transcription-translation assay. Activation by FIXJ was dependent on the sigma 70 holoenzyme form of RNA polymerase.