Glutamine auxotrophs with mutations in a nitrogen regulatory gene, ntrC, that is near glnA

Coupling AAA protein function to regulated gene expression

AAA proteins (ATPases Associated with various cellular Activities) are involved in almost all essential cellular processes ranging from DNA replication, transcription regulation to protein degradation. One class of AAA proteins has evolved to adapt to the specific task of coupling ATPase activity to activating transcription. These upstream promoter DNA bound AAA activator proteins contact their target substrate, the σ(54)-RNA polymerase holoenzyme, through DNA looping, reminiscent of the eukaryotic enhance binding proteins. These specialised macromolecular machines remodel their substrates through ATP hydrolysis that ultimately leads to transcriptional activation. We will discuss how AAA proteins are specialised for this specific task.

Managing membrane stress: the phage shock protein (Psp) response, from molecular mechanisms to physiology

The bacterial phage shock protein (Psp) response functions to help cells manage the impacts of agents impairing cell membrane function. The system has relevance to biotechnology and to medicine. Originally discovered in Escherichia coli, Psp proteins and homologues are found in Gram-positive and Gram-negative bacteria, in archaea and in plants. Study of the E. coli and Yersinia enterocolitica Psp systems provides insights into how membrane-associated sensory Psp proteins might perceive membrane stress, signal to the transcription apparatus and use an ATP-hydrolysing transcription activator to produce effector proteins to overcome the stress. Progress in understanding the mechanism of signal transduction by the membrane-bound Psp proteins, regulation of the psp gene-specific transcription activator and the cell biology of the system is presented and discussed. Many features of the action of the Psp system appear to be dominated by states of self-association of the master effector, PspA, and the transcription activator, PspF, alongside a signalling pathway that displays strong conditionality in its requirement.

Repressor mutant forms of the Azospirillum brasilense NtrC protein

The Azospirillum brasilense mutant strains FP8 and FP9, after treatment with nitrosoguanidine, showed a null Nif phenotype and were unable to use nitrate as their sole nitrogen source. Sequencing of the ntrC genes revealed single nucleotide mutations in the NtrC nucleotide-binding site. The phenotypes of these strains are discussed in relation to their genotypes.

Mutations affecting motifs of unknown function in the central domain of nitrogen regulatory protein C

The positive control function of the bacterial enhancer-binding protein NtrC resides in its central domain, which is highly conserved among activators of sigma54 holoenzyme. Previous studies of a small set of mutant forms specifically defective in transcriptional activation, called NtrC repressor [NtrC(Rep)] proteins, had enabled us to locate various functional determinants in the central domain. In this more comprehensive survey, the DNA encoding a major portion of the central domain was randomly mutagenized and mutated ntrC genes were introduced into the cell via multicopy expression plasmids. DNA sequencing of 95 isolates identified by a preliminary phenotypic screen revealed that the lesions in them caused 55 distinct single amino acid substitutions at 44 different positions. Assays of glnA transcription in vivo and in vitro yielded two conclusions. First, of the 41 mutant proteins that could be purified, 17 (1 known, 16 new) showed no detectable activity in either assay, thus qualifying them as true NtrC(Rep) proteins. These contained residue changes in six of the seven highly conserved regions in the central domain, including two never studied before. Second, some mutant proteins were inactive in vivo but were either marginally or fully active in vitro. Their surprising lack of activity in vivo may be accounted for by high levels of expression, which apparently decreased activation by these mutant proteins but not by wild-type NtrC (NtrCWT). Of particular interest were a subset of these proteins that exhibited greater transcriptional activation than NtrCWT at low concentrations. Their elevated activation capacities remain to be explained.

In vivo studies on the positive control function of NifA: a conserved hydrophobic amino acid patch at the central domain involved in transcriptional activation

The eubacterial enhancer-binding proteins activate transcription by binding to distant sites and, simultaneously, contacting the RNA polymerase r54 promoter complex (Esigma54). The positive control function is located at the central domain of these proteins, but it is not know which specific region has the determinants for the interaction with Esigma54. Here, we present genetic evidence that a small region of hydrophobic amino acids, previously denominated C3, at the central domain of Bradyrhizobium japonicum NifA is involved in positive control. We obtained 26 missense mutants along this conserved region. Among these, only strains expressing the NifA(F307-->Y) and NifA(A310-->S) mutant proteins retained some of the transcriptional activity (<20%), whereas those carrying NifA(E298-->D) and NifA(T308-->S) had very low but detectable activity (< 1.0%). The rest of the NifA mutants did not induce any measurable transcriptional activity. When expressed in the presence of wild-type NifA, the great majority of the mutants displayed a dominant phenotype, suggesting that their oligomerization determinants were not altered. In vivo dimethyl-sulphate footprinting experiments for a subset of the NifA mutants showed that they were still able to bind specifically to DNA. Analysis of intragenic supressors highlight the functional role of a hydroxyl group at position 308 to activate transcription.

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.

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.

The phosphorylated form of the enhancer-binding protein NTRC has an ATPase activity that is essential for activation of transcription

The NTRC protein of enteric bacteria is an enhancer-binding protein that activates transcription in response to limitation of combined nitrogen. NTRC activates transcription by catalyzing formation of open complexes by RNA polymerase (sigma 54 holoenzyme form) in an ATP-dependent reaction. To catalyze open complex formation, NTRC must be phosphorylated. We show that phosphorylated NTRC has an ATPase activity, and we present biochemical and genetic evidence that NTRC must hydrolyze ATP to catalyze open complex formation. It is likely that all activators of sigma 54 holoenzyme have an ATPase activity.

Analysis of the Klebsiella pneumoniae ntrB gene by site-directed in vitro mutagenesis

A number of in-frame insertion and deletion mutations have been constructed in vitro in the Klebsiella pneumoniae ntrB gene and the effects of each mutant NtrB protein on NtrC activity have been assessed after reintroduction of the ntrB mutation into the glnA ntrBC operon. These experiments suggest that the phosphorylation of NtrC catalysed by NtrB not only makes NtrC competent as a transcriptional activator but also improves the DNA-binding properties and hence the negative control functions of NtrC. The variety of NtrB phenotypes obtained suggest a structure/function model for the protein.

Interaction of purified NtrC protein with nitrogen regulated promoters from Klebsiella pneumoniae

The product of the Klebsiella pneumoniae nitrogen regulatory gene ntrC has been purified and shown to be a dimeric protein of subunit molecular weight 54Kd, designated NtrC. In an in vitro coupled transcription-translation system NtrC inhibited expression from both the ntrBC and glnA promoters. NtrC bound to both of these ntr repressible promoters with equal affinity, but did not bind to the activatable nitrogen fixation promoters nifF or nifLA. NtrC makes contact with nucleotides flanking the -10 region of the glnA (RNA2) promoter at sequences homologous with the proposed consensus binding site.

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.

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.

Simple, rapid, and quantitative release of periplasmic proteins by chloroform

We introduce a method by which periplasmic proteins can be released rapidly, simply, and quantitatively by treating cells with chloroform. All the amino acid-binding proteins tested maintained their activity during chloroform treatment. This method makes practical the analysis of the periplasmic protein complement of a large number of strains.

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.

cis-Dominant, glutamine synthetase constitutive mutations of Escherichia coli independent of activation by the glnG and glnF products

Mutants resistant to 80 microM L-methionine-DL-sulfoximine (MS) were isolated on glucose-minimal 15 mM NH4+ medium plates from Escherichia coli cells which were hypersensitive to this concentration of the analogue by virtue of their harboring glnG mutations. MS-resistant mutants derived from strain MX902 carried, in addition to its glnG74 ::Tn5 allele, mutations tightly linked to glnA, as shown by P1-mediated transduction experiments. One particular allele, gln-76, which suppressed the MS-sensitivity conferred by glnG74 ::Tn5 but not its Ntr- phenotype (inability to transport and utilize compounds such as arginine or proline as the only nitrogen sources), was shown to allow constitutive expression of glutamine synthetase in the absence not only of a functional glnG product but also of a functional glnF product. This behavior was found to be cis-dominant in complementation experiments with F'14 merogenotes . In an otherwise wild-type genetic background as in MX929 (gln-76 glnA+ glnL+ glnG+ glnF +), however, normal activation, mediated by the glnG and glnF products was preferred over that mediated by gln-76.

Methionine and glutamine transport systems in D-methionine utilising revertants of Salmonella typhimurium

In Salmonella typhimurium, methionine auxotrophs such as metB can use D-methionine as a methionine source. MetP mutations prevent this growth since D-methionine can enter only via the metP high-affinity methionine transport system. D-methionine utilising revertants ( Dmu +) were selected from metB23 metP760 ( HU76 ) following nitrosoguanidine mutagenesis. The properties of two such revertants, HU206 and HU415 , indicated that reversion was not due to backmutation of the metP760 mutation. Genetic analysis indicated that each strain possessed two mutations, designated dmu and gln, in addition to the original metB23 and metP760 mutations. The dmu mutation restores ability to grow on D-methionine, partly restores D- and L-methionine transport activity, and makes the cells particularly sensitive to inhibition by L-glutamine while growing on D but not L-methionine. The growth inhibition by L-glutamine was shown to be caused by competition by L-glutamine for D-methionine transport by the high-affinity methionine system. The gln mutation greatly reduces activity of the high-affinity glutamine transport system. The Dmu + strains are also partly defective in the glutamine low-affinity transport system, possibly because the partially-restored methionine high-affinity system, or a component of tis system, functions in the transport of glutamine by its low-affinity system.

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

Previous work has indicated that nitrogen regulatory genes ntrB and ntrC of Salmonella typhimurium are closely linked to glnA, the structural gene encoding glutamine synthetase; proceeding clockwise the order of genes in the 86 U region of the map is polA...ntrC ntrB glnA glnA promoter...rha. To study ntrC transcription we have constructed operon fusions of ntrC to lacZ using the Casadaban Mu d1 (Apr lac) phage so that we can measure beta-galactosidase activity as a reflection of ntrC transcription and we have introduced into fusion strains promoter constitutive mutations at glnA [glnAp(Con)]. The glnAp(Con) mutations, which elevate glnA expression in fusion strains, also elevate beta-galactosidase activity, indicating that ntrC is cotranscribed with glnA. Consistent with this interpretation, polar insertion mutations in glnA decrease beta-galactosidase activity of fusion strains carrying glnAp(Con) mutations. However, glnA insertions do not eliminate beta-galactosidase activity of glnAp(Con) ntrC::Mu d1 strains and they have little effect on beta-galactosidase activity of the original ntrC::Mu d1 fusion strains. The latter results confirm that ntrC can also be transcribed from an ntr promoter downstream of glnA. Polar insertion mutations in ntrB eliminate beta-galactosidase activity of both the original fusion strains and fusion strains carrying glnA(Con) mutations, indicating that the ntr promoter lies between glnA and ntrB.

Regulation of transcription of glnA, the structural gene encoding glutamine synthetase, in glnA::Mu d1 (ApR, lac) fusion strains of Salmonella typhimurium

Using the Casadaban Mu d1 phage (Casadaban and Cohen 1979) we fused cis-acting regulatory sites for the Salmonella typhimurium glnA gene, the structural gene encoding glutamine synthetase, to lacZ so that transcription of lacZ was controlled by the glnA promoter-operator. Activities of beta-galactosidase in two glnA::Mu d1 fusion strains were high, approximately 25% and 125% the induced level of beta-galactosidase when transcription of lacZ is under control of the lac promoter, indicating that glutamine synthetase is not required to activate transcription of its own structural gene. Introduction of nitrogen regulatory mutations ntrA::Tn10 or ntrC::Tn10 into fusion strains resulted in greatly decreased synthesis of beta-galactosidase indicating that the positive regulatory factors encoded by ntrA and ntrC activate glnA expression at the level of transcription. Comparison of beta-galactosidase activities in fusion strains with those in fusions carrying ntrC or ntrA mutations indicated that: 1) the magnitude of activation of glnA expression is at least 43-fold; 2) the magnitude of repression is approximately 13-fold and repression occurs at the level of transcription; 3) the degree of modulation of glnA expression by ntr products is at least 560-fold (13 X 43); and 4) glutamine synthetase is not required for repression of transcription of its own structural gene. In contrast to strains carrying non-polar mutations in glnA, strains carrying glnA insertion mutations, including glnA::Mu d1 fusions, are apparently defective in activating expression of some nitrogen controlled genes other than glnA. Defects cannot be accounted for by the absence of glutamine synthetase protein or catalytic activity; they appear to be due to decreased expression of nitrogen regulatory genes ntrB and/or ntrC, which are adjacent to glnA.

Overproduction of nitrogenase by nitrogen-limited cultures of Rhodopseudomonas palustris

Rhodopseudomonas palustris cells grown on limiting nitrogen produced four- to eightfold higher nitrogenase specific activity relative to cells sparged with N2. The high activity of N-limited cells was the result of overproduction of the nitrogenase proteins. This was shown by four independent techniques: (i) titration of the Mo-Fe protein in cell-free extracts with Fe protein from Azotobacter vinelandii; (ii) direct detection of the subunits of Mo-Fe protein by sodium dodecyl sulfate-polyacrylamide gel electrophoresis; (iii) monitoring of the electron paramagnetic resonance spectrum of Mo-Fe protein in whole cells; and (iv) immunological assay of the Fe protein level with an antiserum against the homologous protein of Rhodospirillum rubrum. The derepressed level of nitrogenase found in N2-grown cells was not due to an increased turnover of nitrogenase. The apparent half-lives of nitrogenase in N2-grown and N-limited cells were 58 and 98 h, respectively, but were too long to account for the difference in enzyme level. Half-lives were determined by measuring nitrogenase after repression of de novo synthesis by ammonia and subsequent release of nitrogenase switch-off by methionine sulfoximine. Observations were extended to R. rubrum, Rhodopseudomonas capsulata, and Rhodomicrobium vannielii and indicated that overproduction of nitrogenase under nitrogen limitation is not an exceptional property of R. palustris, but rather a general property of phototrophic bacteria.

Positive control and autogenous regulation of the nifLA promoter in Klebsiella pneumoniae

The nitrogen fixation (nif) genes of Klebsiella pneumoniae are specifically regulated by the products of the nifLA operon. We have located the promoter of this operon, and identified sequences required for nifLA transcription. Transcription from this promoter is shown to be positively regulated by the ntrC gene product (which coordinates the expression of many operons required for nitrogen assimilation) and also autogenously by the product of the nifA gene.

Characterization of glutamine-requiring mutants of Pseudomonas aeruginosa

Revertants were isolated from a glutamine-requiring mutant of Pseudomonas aeruginosa PAO. One strain showed thermosensitive glutamine requirement and formed thermolabile glutamine synthase, suggesting the presence of a mutation in the structural gene for glutamine synthetase. The mutation conferring glutamine auxotrophy was subsequently mapped and found to be located at about 15 min on the chromosomal map, close to and before hisII4. Furthermore, in transduction experiments, it appeared to be very closely linked to gln-2022, a suppressor mutation affecting nitrogen control. With immunological techniques, it could be demonstrated that the glutamine auxotrophs form an inactive glutamine synthetase protein which is regulated by glutamine or a product derived from it in a way similar to other nitrogen-controlled proteins.

Cloning of the glnA, ntrB and ntrC genes of Klebsiella pneumoniae and studies of their role in regulation of the nitrogen fixation (nif) gene cluster

The glnA, ntrB and ntrC genes of Klebsiella pneumoniae have been cloned, on a 12 kb HindIII fragment, into the plasmid pACYC184. In a coupled in vitro transcription/translation system the resultant plasmid, pGE100, directed synthesis of five polypeptides (molecular weights 73, 53, 51, 39, 36 kd) from the cloned fragment. A number of plasmids were derived from pGE100 and studied by complementation analysis and in vitro transcription/translation in order to locate particular genes and identify their products. On the basis of the results presented here, together with previous genetic and physical characterisation of the glnA gene and its product in other enteric bacteria, we propose that the 53 kd polypeptide is the glnA gene product (glutamine synthetase monomer). Two polypeptides (36 kd and 51 kd) were synthesised from a 3 kb region previously defined as glnR. In E. coli and S. typhimurium this region comprises two genes ntrB and ntrC with products of 36 kd and 54 kd respectively. This analogy supports the idea that the 36 kd and 51 kd polypeptides are the products of the K. pneumoniae ntrB and ntrC genes respectively. Comparison of these assignments with the physical map of the region indicates a gene order glnA, ntrB, ntrC. Assessment of the Nif phenotype of a glnA-ntrC deletion strain carrying various clones from pGE100 demonstrated that glnA is not required for expression of the nif regulon and that of the three genes cloned, ntrC alone is sufficient for nif expression.