Evidence that nitrogen regulatory gene ntrC of Salmonella typhimurium is transcribed from the glnA promoter as well as from a separate ntr promoter

Distinct roles of an alternative sigma factor during both free-swimming and colonizing phases of the Vibrio cholerae pathogenic cycle

Vibrio cholerae, the bacterium that causes cholera, has a pathogenic cycle consisting of a free-swimming phase outside its host, and a sessile virulent phase when colonizing the human small intestine. We have cloned the V. cholerae homologue of the rpoN gene (encoding sigma54) and determined its role in the cholera pathogenic cycle by constructing an rpoN null mutant. The V. cholerae rpoN mutant is non-motile; examination of this mutant by electron microscopy revealed that it lacks a flagellum. In addition to flagellar synthesis, sigma54 is involved in glutamine synthetase expression. Moreover, the rpoN mutant is defective for colonization in an infant mouse model of cholera. We present evidence that the colonization defect is distinct from the non-motile and Gln phenotypes of the rpoN mutant, implicating multiple and distinct roles of sigma54 during the V. cholerae pathogenic cycle. RNA polymerase containing sigma54 (sigma54-holoenzyme) has an absolute requirement for an activator protein to initiate transcription. We have identified three regulatory genes, flrABC (flagellar regulatory proteins ABC) that are additionally required for flagellar synthesis. The flrA and flrC gene products are sigma54-activators and form a flagellar transcription cascade. flrA and flrC mutants are also defective for colonization; this phenotype is probably independent of non-motility. An flrC constitutive mutation (M114-->I) was isolated that is independent of its cognate kinase FlrB. Expression of the constitutive FlrCM114-->I from the cholera toxin promoter resulted in a change in cell morphology, implicating involvement of FlrC in cell division. Thus, sigma54 holoenzyme, FlrA and FlrC transcribe genes for flagellar synthesis and possibly cell division during the free-swimming phase of the V. cholerae life cycle, and some as yet unidentified gene(s) that aid colonization within the host.

NtrC is required for control of Klebsiella pneumoniae NifL activity

In response to molecular oxygen and/or fixed nitrogen, the product of the Klebsiella pneumoniae nitrogen fixation L (nifL) gene inhibits NifA-mediated transcriptional activation. Nitrogen regulation of NifL function occurs at two levels: transcription of the nifLA operon is regulated by the general Ntr system, and the activity of NifL is controlled by an unknown mechanism. We have studied the regulation of NifL activity in Escherichia coli and Salmonella typhimurium by monitoring its inhibition of NifA-mediated expression of a K. pneumoniae phi(nifH'-'lacZ) fusion. The activity of the NifL protein transcribed from the tac promoter is regulated well in response to changes of oxygen and/or nitrogen status, indicating that no nif- or K. pneumoniae-specific product is required. Unexpectedly, strains carrying ntrC (glnG) null alleles failed to release NifL inhibition, despite the fact that synthesis of NifL was no longer under Ntr control. Additional evidence indicated that it is indeed the transcriptional activation capacity of NtrC, rather than its repression capacity, that is needed, and hence it is a plausible hypothesis that NtrC activates transcription of a gene(s) whose product(s) in turn functions to relieve NifL inhibition under nitrogen-limiting conditions.

Simultaneous prevention of glutamine synthesis and high-affinity transport attenuates Salmonella typhimurium virulence

In Salmonella typhimurium, transcription of the glnA gene (encoding glutamine synthetase) is under the control of the nitrogen-regulatory (ntr) system comprising the alternate sigma factor sigma54 (NtrA) and the two-component sensor-transcriptional activator pair NtrB and NtrC. The glnA, ntrB, and ntrC genes form an operon. We measured the virulence of S. typhimurium strains with nitrogen-regulatory mutations after intraperitoneal (i.p.) or oral inoculations of BALB/c mice. Strains with single mutations in glnA, ntrA, ntrB, or ntrC had i.p. 50% lethal doses (LD50s) of <10 bacteria, similar to the wild-type strain. However, a strain with a delta(glnA-ntrC) operon deletion had an i.p. LD50 of >10(5) bacteria, as did delta glnA ntrA and delta glnA ntrC strains, suggesting that glnA strains require an ntr-transcribed gene for full virulence. High-level transcription of the glutamine transport operon (glnHPQ) is dependent upon both ntrA and ntrC, as determined by glnHp-lacZ fusion measurements. Moreover, delta glnA glnH and delta glnA glnQ strains are attenuated, similar to delta glnA ntrA and delta glnA ntrC strains. These results reveal that access of S. typhimurium to host glutamine depends on the ntr system, which apparently is required for the transcription of the glutamine transport genes. The delta(glnA-ntrC) strain exhibited a reduced ability to survive within the macrophage cell line J774, identifying a potential host environment with low levels of glutamine. Finally, the delta(glnA-ntrC) strain, when inoculated at doses as low as 10 organisms, provided mice with protective immunity against challenge by the wild-type strain, demonstrating its potential use as a live vaccine.

Nitrogen control in bacteria

Nitrogen metabolism in prokaryotes involves the coordinated expression of a large number of enzymes concerned with both utilization of extracellular nitrogen sources and intracellular biosynthesis of nitrogen-containing compounds. The control of this expression is determined by the availability of fixed nitrogen to the cell and is effected by complex regulatory networks involving regulation at both the transcriptional and posttranslational levels. While the most detailed studies to date have been carried out with enteric bacteria, there is a considerable body of evidence to show that the nitrogen regulation (ntr) systems described in the enterics extend to many other genera. Furthermore, as the range of bacteria in which the phenomenon of nitrogen control is examined is being extended, new regulatory mechanisms are also being discovered. In this review, we have attempted to summarize recent research in prokaryotic nitrogen control; to show the ubiquity of the ntr system, at least in gram-negative organisms; and to identify those areas and groups of organisms about which there is much still to learn.

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.

Protein phosphorylation and regulation of adaptive responses in bacteria

Bacteria continuously adapt to changes in their environment. Responses are largely controlled by signal transduction systems that contain two central enzymatic components, a protein kinase that uses adenosine triphosphate to phosphorylate itself at a histidine residue and a response regulator that accepts phosphoryl groups from the kinase. This conserved phosphotransfer chemistry is found in a wide range of bacterial species and operates in diverse systems to provide different regulatory outputs. The histidine kinases are frequently membrane receptor proteins that respond to environmental signals and phosphorylate response regulators that control transcription. Four specific regulatory systems are discussed in detail: chemotaxis in response to attractant and repellent stimuli (Che), regulation of gene expression in response to nitrogen deprivation (Ntr), control of the expression of enzymes and transport systems that assimilate phosphorus (Pho), and regulation of outer membrane porin expression in response to osmolarity and other culture conditions (Omp). Several additional systems are also examined, including systems that control complex developmental processes such as sporulation and fruiting-body formation, systems required for virulent infections of plant or animal host tissues, and systems that regulate transport and metabolism. Finally, an attempt is made to understand how cross-talk between parallel phosphotransfer pathways can provide a global regulatory curcuitry.

Evidence that the Myxococcus xanthus frz genes are developmentally regulated

The frizzy (frz) mutants of Myxococcus xanthus are unable to form fruiting bodies. Instead of forming discrete mounds, these strains aggregate as filaments which have a circular and tangled appearance. Mutations leading to this phenotype have been mapped to five complementation groups, frzA, frzB, frzCD, frzE, and frzF. All have been found to be involved in the control of directional movement of the bacteria and, except for frzB, to be homologous to the chemotaxis genes of enteric bacteria. In this report we present a study of the regulation of expression of the first four genes of the frz gene cluster (frzA, frzB, frzCD, and frzE) by using Tn5-lac transcriptional fusions as reporters of gene expression. We found that these frz genes are developmentally regulated, with their transcription peaking at about the time of early mound formation (12 to 18 h). Analysis of FrzCD expression by enzyme-linked immunosorbent assay showed a 10-fold greater induction at 15 h of development over the level of vegetative cell expression. Northern blot hybridization analysis suggested that the frz genes were arranged as an operon. To test this hypothesis, double mutants were constructed which contained Tn5-132 either upstream or downstream of the reporter Tn5-lac. The expression of the frz genes in the double mutants was consistent with the hypothesis that the first four genes (frzA, frzB, frzCD, and frzE) are organized as an operon with an internal promoter. Insertion mutations in frzCD lowered gene expression whether they were upstream or downstream of the reporter Tn5-lac, suggesting that the FrzCD protein regulates transcription of the entire operon from a promoter upstream of frzA. Evidence is presented suggesting that FrzE is required for induction of transcription as well. When frz mutations were placed in strains that were unable to aggregate (tag), the frz genes were expressed at an elevated level on fruiting agar; this high level of expression was maintained for several days. These results suggest that the tag gene products interact with the frz functions.

Nucleotidylation, not phosphorylation, is the major source of the phosphotyrosine detected in enteric bacteria

The majority of the phosphotyrosine recovered from partial acid hydrolysates of 32P-labeled Escherichia coli is derived from a single prominent protein. We show here by biochemical, genetic, and immunological criteria that this protein is actually glutamine synthetase adenylylated (not phosphorylated) at tyrosine. Furthermore, all of the phosphotyrosine detectable in partial acid hydrolysates of 32P-labeled Salmonella typhimurium was eliminated in a strain deficient in both glutamine synthetase and uridylyltransferase, an enzyme which uridylylates the regulatory protein PII at a tyrosine residue. These results suggest that protein-tyrosine phosphorylation represents a rare modification in eubacterial cells.

The effect on the function of the transcriptional activator NtrC from Klebsiella pneumoniae of mutations in the DNA-recognition helix

We have constructed mutations in what we predict to be the DNA-recognition helix of Klebsiella pneumoniae NtrC, which regulates transcription from promoters under global nitrogen control. Mutations which disrupt the helix lead to complete loss of function. All point mutants tested were able to activate transcription from the sigma 54-dependent glnA promoter, but only those retaining some ability to recognise NtrC binding sites, as evidenced by their ability to repress the ntrB promoter and the upstream glnA promoter, were able to activate the nifL promoter. One mutant, which contained an amino acid substitution in the turn of the DNA-binding motif as well as in the recognition helix, suppressed mutations in the NtrC binding sites upstream from the nifL promoter, but only if both sites bore equivalent transitions. This confirms that the DNA-binding motif for this class of transcriptional activator has been correctly identified and suggests that binding of NtrC can be cooperative.

The nucleotide sequence of the sigma factor gene ntrA (rpoN) of Azotobacter vinelandii: analysis of conserved sequences in NtrA proteins

The nucleotide sequence of the Azotobacter vinelandii ntrA gene has been determined. It encodes a 56916 Dalton acidic polypeptide (AvNtrA) with substantial homology to NtrA from Klebsiella pneumoniae (KpNtrA) and Rhizobium meliloti (RmNtrA). NtrA has been shown to act as a novel RNA polymerase sigma factor but the predicted sequence of AvNtrA substantiates our previous analysis of KpNtrA in showing no substantial homology to other known sigma factors. Alignment of the predicted amino acid sequences of AvNtrA, KpNtrA and RmNtrA identified three regions; two showing greater than 50% homology and an intervening sequence of less than 10% homology. The predicted protein contains a short sequence near the centre with homology to a conserved region in other sigma factors. The C-terminal region contains a region of homology to the beta' subunit of RNA polymerase (RpoC) and two highly conserved regions one of which is significantly homologous to known DNA-binding motifs. In A. vinelandii, ntrA is followed by another open reading frame (ORF) which is highly homologous to a comparable ORF downstream of ntrA in K. pneumoniae and R. meliloti.

The complete nucleotide sequence of the glnALG operon of Escherichia coli K12

The nucleotide sequence of the E. coli glnALG operon has been determined. The glnL (ntrB) and glnG (ntrC) genes present a high homology, at the nucleotide and aminoacid levels, with the corresponding genes of Klebsiella pneumoniae. The predicted aminoacid sequence for glutamine synthetase allowed us to locate some of the enzyme domains. The structure of this operon is discussed.

Organization, structure and symbiotic function of Rhizobium meliloti nodulation genes determining host specificity for alfalfa

In R. meliloti we have identified four nodulation genes determining plant host-range specificity and have designated them hsnABC and D. The genes code for 9.7, 41.7, 26.7, and 28.6 kd proteins, respectively, and are organized into two transcriptional units. Mutations in these genes affect nodulation of their natural plant hosts Medicago sativa and Melilotus albus to different extents and hsnD mutants have an altered host-range. These Nod- mutations are not complementable by nodulation genes of other Rhizobium species such as R. leguminosarum. The hsn genes determine plant-specific infection through root hairs: hsnD is required for host-specific root hair curling and nodule initiation while the hsnABC genes control infection thread growth from the root hairs.

Glutamine synthetase-constitutive mutation affecting the glnALG upstream promoter of Escherichia coli

The spontaneous gln-76 mutation of Escherichia coli (Osorio et al., Mol. Gen. Genet. 194:114-123, 1984) was previously shown to be responsible for the cis-dominant constitutive expression of the glnA gene in the absence of a glnG-glnF activator system. Nucleotide sequence analysis has now revealed that gln-76 is a single transversion T.A to A.T, an up-promoter mutation affecting the -10 region of glnAp1, the upstream promoter of the glnALG control region. Both, wild-type and gln-76 DNA control regions were cloned into the promoter-probe plasmid pKO1. Galactokinase activity determinations of cells carrying the fused plasmids showed 10-fold more effective expression mediated by gln-76 than by the glnA wild-type control region. Primer extension experiments with RNA from strains carrying the gln-76 control region indicated that the transcription initiation sites were the same in both the gln-76 mutant and the wild type.

The nucleotide sequence of the nitrogen regulation gene ntrB and the glnA-ntrBC intergenic region of Klebsiella pneumoniae

The nucleotide sequence of the Klebsiella pneumoniae ntrB gene and the glnA-ntrBC intergenic region has been determined. NtrB encodes a 38,409 Dalton polypeptide with a potential DNA-binding domain between residues 67 and 86. This N-terminal domain may play a role in the co-operative control of ntr-regulated promoters by the ntrB and ntrC products. Mapping of in vivo transcripts with S1 nuclease identified three transcripts in the glnA-ntrBC intergenic region. Two transcripts originate upstream of glnA; one reading through into ntrBC and one terminating at a sequence resembling a rho-independent terminator between glnA and ntrBC. A third transcript originates from the ntrBC promoter which has a consensus binding site for the ntrC product in the -10 region. Comparison of the glnA-ntrBC intergenic sequences from K. pneumoniae, Escherichia coli and Salmonella typhimurium has identified a number of conserved features and some significant differences.

Products of nitrogen regulatory genes ntrA and ntrC of enteric bacteria activate glnA transcription in vitro: evidence that the ntrA product is a sigma factor

In enteric bacteria the products of two nitrogen regulatory genes, ntrA and ntrC, activate transcription of glnA, the structural gene encoding glutamine synthetase, both in vivo and in vitro. The ntrC product (gpntrC) is a DNA-binding protein, which binds to five sites in the glnA promoter-regulatory region and appears to activate transcription initiation. Using as an assay the stimulation of glnA transcription in a coupled in vitro transcription-translation system, we have partially purified the ntrA gene product (gpntrA). The following evidence is consistent with the view that gpntrA is a sigma subunit for RNA polymerase: (i) The gpntrA activity copurifies with the sigma 70 holoenzyme (E sigma 70) and core (E) forms of RNA polymerase through several steps but can be separated from them by chromatography on heparin agarose. (ii) After further purification by molecular sieve chromatography, the partially purified gpntrA fraction allows transcription of glnA from the same startpoint used in vivo; transcription is dependent on gpntrC and on added E. The gpntrA fraction does not allow transcription from promoters that we have used as controls, including lacUV5. E sigma 70 has the reverse specificity.

Expression of glnA in Escherichia coli is regulated at tandem promoters

We have determined that the glnA gene of the complex glnALG operon of Escherichia coli is transcribed from tandem promoters. Expression from the upstream promoter, glnAp1, requires the catabolite activating protein, is repressed by nitrogen regulator I (NRI), the product of glnG, and produces a transcript with an untranslated leader of 187 nucleotides. Expression from the downstream promoter, glnAp2, requires NRI as well as the glnF product; full expression also requires growth in a nitrogen-limited environment. The downstream transcript has an untranslated leader of 73 nucleotides. We also provide evidence that the function of the glnL product is to mediate the interconversion of NRI between a form capable of activating glnAp2 and an inactive form in response to changes in the intracellular concentration of ammonia. The function of the two minor promoters of the glnALG operon, glnAp1 and glnLp, is to maintain the products of glnA, glutamine synthetase, an essential enzyme, and of glnG, NRI, an activator of nitrogen-controlled genes, during carbon-limited growth.

Nucleotide sequence of the glnA-glnL intercistronic region of Escherichia coli

The nucleotide (nt) sequence of a 682-bp fragment containing the 3' end of the glnA gene, the region between the glnA and glnL genes, and the 5' end of the glnL gene from Escherichia coli was determined. This segment contains the region coding for the last 107 amino acids (aa) of glutamine synthetase, including the adenylylation site of this enzyme. The analysis of this sequence revealed two REP sequences, a Rho-independent terminator, the putative glnL promoter and the possible binding site for the glnG product, NRI.

Catabolism and nitrogen control in Escherichia coli

It would appear from these studies that nitrogen control reflects the catabolic capacity of the cell and that utilizable nitrogen sources and some carbon sources are, to some extent, in competition for this capacity. The series of catabolic events initiated by addition of D-amino acids or by growth on aldol sugars, in the presence of ammonia nitrogen in the growth medium, provide an opportunity for study of the positive aspect of nitrogen control under conditions where negative control predominates. This approach may eventually clarify the apparent interactions between the modification cascade components, PII and UT/UR, with the nitrogen regulatory gene, glnG. The utilization of nutrients by E. coli seems less a matter of energy than of expeditious use of whatever is offered in the diet. A comparison of the rate of increase of GS on cultural downshift with the rate of increase following D-glutamate addition would suggest that control by nitrogen limitation is about eight times more effective than positive activation by D-glutamate in the presence of ammonia nitrogen. This observation is consistent with the finding of an additive effect for the D-amino acids which can function as positive activators in GS regulation. It has been demonstrated for the wild-type organism that the increase in GS level generated by a mixture of D-glutamate, D-lysine, D-threonine, and glycine approximates the increase in GS level observed during step-down of the culture from an ammonia-sufficient to an ammonia-limited condition. This observation further supports the physiologic relevance of the effect of D-amino acids in nitrogen control and suggests that the apparent derepression of GS observed upon exhaustion of the ammonia nitrogen supply represents a composite of positive activation generated as alternative catabolic functions assume a greater importance. As might be expected, addition of D-glutamate to cells at the point of ammonia exhaustion had no additional positive effect. Following a downshift from glucose-ammonia-glutamine to glucose-glutamine cultural conditions, only the level of GS increases during the initial 60-minute observation period. This finding suggests that glutamine catabolism may, like D-threonine, D-lysine, and glycine, bypass the positive activation of GDH and GAT controls. The likely possibility in that the increases observed for GAT and GDH depend on D-glutamate as specific inducer. There are several instances where D-amino acids function as inducers of L-amino acid dehydrogenases and where amino acid racemase activity is directly coupled to flavoprotein dehydrogenases.(ABSTRACT TRUNCATED AT 400 WORDS)

Tandem promoters determine regulation of the Klebsiella pneumoniae glutamine synthetase (glnA) gene

Transcription of the structural gene for glutamine synthetase (glnA) in Klebsiella pneumoniae is controlled by the nitrogen regulatory genes ntrA, ntrB and ntrC. The nucleotide sequence of the regulatory region upstream of the glnA gene is reported here. High resolution S1 mapping of in vivo transcripts indicates that the regulatory region contains tandem promoters separated by 100 nucleotides. Measurements of beta-galactosidase activities determined in vivo from glnA-lac fusions suggest that the upstream promoter (for RNA2) is negatively regulated by the ntrBC gene products whereas transcription from the downstream promoter (for RNA1) is positively activated by the ntrA gene product in the presence of either the ntrBC or the nifA genes. The nucleotide sequence of the upstream promoter resembles the consensus sequence for E. coli promoters, whereas the downstream promoter shows homology with the nitrogen fixation (nif) promoters of K. pneumoniae.

Characterization of mutations that lie in the promoter-regulatory region for glnA, the structural gene encoding glutamine synthetase

In enteric bacteria products of nitrogen regulatory genes ntrA, ntrB and ntrC are known to regulate transcription both positively and negatively at glnA, the structural gene encoding glutamine synthetase [L-glutamate:ammonia-ligase (ADP-forming), EC 6.3.1.2]. We have characterized two types of cis-acting mutations in the glnA promoter-regulatory region. One type, which we have called promoter Up [glnAp (Up)], elevates transcription of glnA to high levels without need for ntr-mediated activation but leaves expression sensitive to ntr-mediated repression. The other type renders glnA transcription insensitive to repression but leaves it normally responsive to activation. Properties of the two types of promoter-regulatory mutations suggest that sites for ntr-mediated activation of glnA transcription are functionally distinct from sites for ntr-mediated repression.