Complementation analysis of glnA-linked mutations which affect nitrogen fixation in Klebsiella pneumoniae

The ntrC gene of Agrobacterium tumefaciens C58 controls glutamine synthetase (GSII) activity, growth on nitrate and chromosomal but not Ti-encoded arginine catabolism pathways

The ntrC locus of Agrobacterium tumefaciens C58 has been cloned using the Azorhizobium sesbaniae ORS571 ntrC gene as a DNA hybridization probe. Transposon Tn5 mutagenesis of the cloned ntrC locus was carried out and one Tn5 insertion within the region of highest DNA homology with A. sesbaniae ORS571 ntrC was used for gene replacement of the wild-type C58 ntrC gene. The A. tumefaciens ntrC::Tn5 mutant was found to be unable to grow on nitrate as sole nitrogen (N) source, to lack glutamine synthetase (GSII) activity and to be unable to use arginine (or ornithine) as sole N source, unless the Ti-encoded arginine catabolism pathway was induced with small amounts of nopaline. Thus the A. tumefaciens ntrC regulatory gene is essential for (transcriptional) activation of the GSII and nitrate reductase genes, as well as for the chromosomal but not the Ti-borne arginine catabolism pathways.

Potential roles for the glnB and ntrYX genes in Azospirillum brasilense

Three Azospirillum brasilense mutants constitutive for nitrogen fixation (Nif(C)) in the presence of NH4(+) and deficient in nitrate-dependent growth were used as tools to define the roles of the glnB and ntrYX genes in this organism. Mutant HM14 was complemented for nitrate-dependent growth and NH4(+) regulation of nitrogenase by plasmid pL46 which contains the ntrYX genes of A. brasilense. Mutant HM26 was restored for NH4(+) regulation and nitrate-dependent growth by plasmid pJC1, carrying the A. brasilense glnB gene expressed from a constitutive promoter. Mutant HM053, on the other hand, was not complemented for NH4(+) regulation of nitrogenase and nitrate-dependent growth by both plasmids pJCI and pL46. The levels and control of glutamine synthetase activity of all mutants were not affected by both plasmids pL46 (ntrYX) and pJC1 (glnB). These results support the characterization of strains HM14 as an ntrYX mutant and strain HM26 as a glnB mutant and the involvement of ntrYX and glnB in the regulation of the general nitrogen metabolism in A. brasilense.

General nitrogen regulation of nitrate assimilation regulatory gene nasR expression in Klebsiella oxytoca M5al

Klebsiella oxytoca can assimilate nitrate and nitrite by using enzymes encoded by the nasFEDCBA operon. Expression of the nasF operon is controlled by general nitrogen regulation (Ntr) via the NtrC transcription activator and by pathway-specific nitrate and nitrite induction via the NasR transcription antiterminator. This paper reports our analysis of nasR gene expression. We constructed strains bearing single-copy Phi(nasR-lacZ) operon fusions within the chromosomal rhaBAD-rhaSR locus. The expression of DeltarhaBS::[Phi(nasR-lacZ)] operon fusions was induced about 10-fold during nitrogen-limited growth. Induction was reduced in both ntrC and rpoN null mutants, indicating that Ntr control of nasR gene expression requires the NtrC and sigma(N) (sigma(54)) proteins. Sequence inspection of the nasR control region reveals an apparent sigma(N)-dependent promoter but no apparent NtrC protein binding sites. Analysis of site-specific mutations coupled with primer extension analysis authenticated the sigma(N)-dependent nasR promoter. Fusion constructs with only about 70 nucleotides (nt) upstream of the transcription initiation site exhibited patterns of beta-galactosidase expression indistinguishable from Phi(nasR-lacZ) constructs with about 470 nt upstream. Expression was independent of the Nac protein, implying that NtrC is a direct activator of nasR transcription. Together, these results indicate that nasR gene expression does not require specific upstream NtrC-binding sequences, as previously noted for argT gene expression in Salmonella typhimurium (G. Schmitz, K. Nikaido, and G. F.-L. Ames, Mol. Gen. Genet. 215:107-117, 1988).

Ammonia-excreting mutants of Klebsiella pneumoniae with a pleiotropic defect in nitrogen metabolism

Enterobacterial mutants defective in the nitrogen control regulatory system (Ntr) generally display a pleiotropic phenotype with regard to expression and regulation of several enzymes and transport systems involved in the assimilation of N sources. This report describes the isolation and characterization of similar pleiotropic mutants of Klebsiella pneumoniae that cannot be complemented by ntr genes. The strains excreted ammonia, were unable to grow on a number of N sources, and contained low glutamine:2-oxoglutarate amino transferase and normal, but unmodifiable glutamine synthetase activities and a nitrogenase level largely unaffected by ammonium, but still repressible by an amino acid mixture. Genetic studies suggested that this phenotype is due to overexpression of an unknown regulatory protein.

Posttranslational regulation of nitrogenase activity in Azospirillum brasilense ntrBC mutants: ammonium and anaerobic switch-off occurs through independent signal transduction pathways

Nitrogenase activity is regulated by reversible ADP-ribosylation in response to NH4+ and anaerobic conditions in Azospirillum brasilense. The effect of mutations in ntrBC on this regulation was examined. While NH4+ addition to ntrBC mutants caused a partial loss of nitrogenase activity, the effect was substantially smaller than that seen in ntr+ strains. In contrast, nitrogenase activity in these mutants was normally regulated in response to anaerobic conditions. The analysis of mutants lacking both the ntrBC gene products and dinitrogenase reductase activating glycohydrolase (DRAG) suggested that the primary effect of the ntrBC mutations was to alter the regulation of DRAG activity. Although nif expression in the ntr mutants appeared normal, as judged by activity, glutamine synthetase activity was significantly lower in ntrBC mutants than in the wild type. We hypothesize that this lower glutamine synthetase activity may delay the transduction of the NH4+ signal necessary for the inactivation of DRAG, resulting in a reduced response of nitrogenase activity to NH4+. Finally, data presented here suggest that different environmental stimuli use independent signal pathways to affect this reversible ADP-ribosylation system.

The influence of the Klebsiella pneumoniae regulatory gene nifL upon the transcriptional activator protein NifA

The influence of the Klebsiella pneumoniae nifL gene product upon the interaction of the transcriptional activator protein NifA with the nifH promoter has been examined using in vivo dimethylsulphate 'footprinting'. Binding of NifA to the upstream activator sequence (UAS) of the nifH promoter in the presence of the NifL protein was observed under nitrogen-limiting growth conditions. Growth in the presence of NH4+ or addition of NH4+ to nitrogen-limited cells diminished the interaction of NifA with the UAS when NifL was present. Repression of nif transcription by NifL may therefore involve an interaction between NifL and NifA which reduces the affinity of NifA for the UAS.

Regulation of transcription of the glnALG operon of Escherichia coli by protein phosphorylation

The transcription of glnA, the structural gene for glutamine synthetase in enteric bacteria, is regulated by the phosphorylation and dephosphorylation of an effector protein, NRI. In its phosphorylated form the effector activates the initiation of transcription at promoters specific of sigma 54, rather than the abundant sigma 70. The ability of NRI-phosphate to stimulate the formation of open promoter-sigma 54 RNA polymerase complexes is enhanced by specific binding sites, located in the case of glnA 100 and 130 base pairs upstream from the transcriptional start site. These sites can be moved more than 1000 base pairs upstream or downstream without losing their effectiveness. The phosphorylation and dephosphorylation of NRI-NRI-phosphate is catalyzed by the modulator protein NRII. Its activity is controlled by an intracellular signal, the ratio of glutamine to 2-ketoglutarate, which is generated by glutamine synthetase in response to the environmental stimulus, the availability or lack of ammonia. The signal is transduced to the modulator by means of 2 additional proteins: uridylytransferase and PII.

The Klebsiella pneumoniae PII protein (glnB gene product) is not absolutely required for nitrogen regulation and is not involved in NifL-mediated nif gene regulation

The role of the Klebsiella pneumoniae PII protein (encoded by glnB) in nitrogen regulation has been studied using two classes of glnB mutants. In Class I mutants PII appears not to be uridylylated in nitrogen-limiting conditions and in Class II mutants PII is not synthesised. The effects of these mutations on expression from nitrogen-regulated promoters indicate that PII is not absolutely required for nitrogen control. Furthermore the uridylylated form of PII (PII-UMP) plays a significant role in the response to changes in nitrogen status by counteracting the effect of PII on NtrB-mediated dephosphorylation of NtrC. PII is not involved in the nif-specific response to changes in nitrogen status mediated by NifL.

Genetic regulation of nitrate assimilation in Klebsiella pneumoniae M5al

We isolated Mu dI1734 insertion mutants of Klebsiella pneumoniae that were unable to assimilate nitrate or nitrite as the sole nitrogen source during aerobic growth (Nas- phenotype). The mutants were not altered in respiratory (anaerobic) nitrate and nitrite reduction or in general nitrogen control. The mutations were linked and thus defined a single locus (nas) containing genes required for nitrate assimilation. beta-Galactosidase synthesis in nas+/phi(nas-lacZ) merodiploid strains was induced by nitrate or nitrite and was inhibited by exogenous ammonia or by anaerobiosis. beta-Galactosidase synthesis in phi(nas-lacZ) haploid (Nas-) strains was nearly constitutive during nitrogen-limited aerobic growth and uninducible during anaerobic growth. A general nitrogen control regulatory mutation (ntrB4) allowed nitrate induction of phi(nas-lacZ) expression during anaerobic growth. This and other results suggest that the apparent anaerobic inhibition of phi(nas-lacZ) expression was due to general nitrogen control, exerted in response to ammonia generated by anaerobic (respiratory) nitrate reduction.

Cloning and characterization of the glnA gene of Azospirillum brasilense Sp7

A plasmid which, by complementation, restored a Gln+Nif+ phenotype to the Gln-Nif- Azospirillum brasilense mutant 7029, was isolated from a gene bank of total DNA of A. brasilense Sp7 (ATCC 29145) constructed in the broad host range vector pVK100. This plasmid contained the structural gene (glnA) for glutamine synthetase. The glnA gene was mapped by Tn5 insertion and DNA hybridization with a Klebsiella pneumoniae glnA probe. The direction of transcription of glnA was determined. The glnA product was identified as a 50-Kd polypeptide which could be adenylylated in Escherichia coli, and glutamine synthetase activity was characterized in E. coli. Plasmids containing the glnA gene restored glutamine-independent growth and a Nif+ phenotype to Gln-Nif- and Gln-Nifc mutants of Azospirillum.

Transcription of glnA in E. coli is stimulated by activator bound to sites far from the promoter

Transcription of the Escherichia coli glnALG operon, whose products are glutamine synthetase and the regulatory proteins NRII and NRI, is activated by nitrogen deprivation. Initiation of transcription at the nitrogen-regulated promoter glnAp2 requires sigma 60, the product of rpoN (glnF, ntrA), and NRI, the product of glnG (ntrC). We have now shown that the ability of this promoter to be activated by a low intracellular concentration of NRI depends on two binding sites for NRI located approximately 110 and 140 bp, respectively, upstream of the start of transcription. Moving these binding sites more than 1000 bp does not diminish the ability of NRI to stimulate transcription at glnAp2. Thus, the NRI binding sites resemble enhancers in eukaryotic cells.

Site-directed mutagenesis of the Klebsiella pneumoniae nifL and nifH promoters and in vivo analysis of promoter activity

The role of conserved nucleotides in nitrogen-fixation promoter function has been examined using both oligonucleotide and chemical mutagenesis to introduce base changes in the Klebsiella pneumoniae nifL and nifH promoters. Among ten mutations analysed, including six spontaneous mutations, base changes at -12, -13, -14, and -26, located in previously identified conserved sequences, perturbed the activity of the promoters, demonstrating that these sequences are required for transcription. Not all base changes produced similar strong promoter down phenotypes when the nifL and nifH promoters were compared: activation of the nifH promoter by the nifA gene product was less sensitive to base changes in conserved nucleotides than was activation of the equivalently altered nifL promoter by the nifA or ntrC products. We have found that the nifH promoter can be weakly activated by the ntrC product; this activation shows the same down response to base changes seen with ntrC activation of the nifL promoter. We present evidence that the efficient activation of the nifH promoter by nifA (but not ntrC) can be attributed to specific upstream sequences present in the nifH promoter.

The nucleotide sequence of the nitrogen-regulation gene ntrA of Klebsiella pneumoniae and comparison with conserved features in bacterial RNA polymerase sigma factors

The nucleotide sequence of the Klebsiella pneumoniae ntrA gene has been determined. NtrA encodes a 53,926 Dalton acidic polypeptide; a calculated molecular weight which is significantly lower than that determined by SDS polyacrylamide gel analysis. NtrA is followed by another open-reading frame (orf) of at least 75 amino acids. In the spacer region between ntrA and orf there are no apparent transcription termination or promoter sequences and therefore orf may be co-transcribed with ntrA. Previous authors have proposed that NtrA could act as an RNA polymerase sigma factor but the NtrA amino acid sequence does not show a high level of homology to any known sigma factor. However analysis of sequences of five sigma factors from E. coli and B. subtilis has identified two conserved sequences at the C-terminal end of all these polypeptides. These sequences resemble those found in known site-specific DNA-binding domains and may be involved in recognition of conserved -35 and -10 promoter sequences. A similar pair of sequences is present at the C-terminus of NtrA and could play a role in recognition of ntr-activatable promoters.

Expression of Klebsiella pneumoniae nif genes in Proteus mirabilis

Self-transmissible plasmids carrying his and nif genes from Klebsiella pneumoniae have been introduced into three his mutants of Proteus mirabilis: strains 5006-1, WR19 and WR20. Expression of his by the transconjugants was unequivocal, if slightly temperature-sensitive, but none was Nif+ when tested for acetylene reduction in anaerobic glucose medium using inocula from rich or glucose-minimal aerobic agar cultures. Succinate or pyruvate in place of glucose, low glucose, lower temperature or elevated Na2MoO4 did not allow nif expression and no nitrogenase MoFe-protein peptide was detected immunologically after exposure to conditions in which diazotrophic enterobacteria, normal or genetically constructed, derepress nif. One strain, P. mirabilis WR19, carrying the his nif Kmr plasmid pMF250 was examined in detail. The nif activator gene nifA was introduced on the plasmid pCK1. Such derivatives remained Nif- when tested, after aerobic growth on rich agar media, with normal or low glucose, with succinate or with elevated Mo. However, pre-conditioning by aerobic growth on glucose-minimal agar led to subsequent anaerobic expression of nif in glucose medium from pMF250 in WR19 carrying pCK1. NH+4 or proline could serve as N-source in the glucose-minimal agar. Maximum activity was about 5% of that of K. pneumoniae in our assay conditions. Material cross-reacting with anti-serum to the nitrogenase MoFe protein was formed. Nitrogenase activity was not 'switched off' by NH+4. P. mirabilis WR19 (pCK1) showed NH+4-constitutive temperature-sensitive kanamycin resistance (a nif-related phenotype of this plasmid) in aerobic glucose minimal medium.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of Rhizobium japonicum nifH and nifDK operons can be activated by the Klebsiella pneumonia nifA protein but not by the product of ntrC

Rhizobium japonicum nifH'- and nifD'-'lacZ fusions were constructed using the translational fusion vector pMC1403. beta-Galactosidase activities from these fusion plasmids were measured in wild-type, ntrA- and delta(ntrBC) Escherichia coli strains carrying plasmids which overproduced the Klebsiella pneumoniae nifA or ntrC gene products. In contrast to results reported in R. meliloti (ref. in the text) neither nifH nor nifD promoters were activated by the ntrC product. In the presence of nifA gene product, however, beta-galactosidase activity from both nifH and nifD fusion plasmids increased substantially. NifA-mediated activation of these Rhizobium promoters was temperature sensitive and was dependent on the host ntrA product. In order to determine the point at which the fusion transcripts were initiated, RNA was extracted from the wild-type E. coli strain carrying each of the R. japonicum fusion plasmids plus the nifA overproducing plasmid. This RNA was used to perform S1 mapping experiments. NifA-mediated transcription from both R. japonicum promoters, began at the same point as previously determined in soybean root-nodule bacteroids (ref. in the text). The results obtained suggest that there may be differences in the mode of regulation between members of the fast- and slow-growing rhizobia. Also, the results of the S1 mapping experiments indicate that activation of the R. japonicum nitrogenase structural genes may be similar to the activation of nif genes in K. pneumoniae thus raising the possibility that R. japonicum may contain nifA and ntrA-like genes.

Studies on the regulation and function of the Klebsiella pneumoniae ntrA gene

The ntrA gene from Klebsiella pneumoniae has been cloned and the product identified as a 76-kDal acidic polypeptide. An ntrA::lacZ fusion was used to demonstrate that expression of ntrA is not controlled by the nitrogen regulation (ntr) system and is independent of the nitrogen status of the cell. Studies with multicopy plasmids carrying ntrA and rpoD suggest that the ntrA product competes with the rpoD product (sigma 70 of RNA polymerase) in mediating transcription initiation by RNA polymerase at ntrA-dependent promoters. No significant homology between ntrA and rpoD was detected by Southern blotting.

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.

Mutations affecting regulation of the Klebsiella pneumoniae nifH (nitrogenase reductase) promotor

Starting with plasmid pSA30 which contains an intact nifHDKY operon, we selected mutants that no longer inhibited nitrogen fixation in Klebsiella pneumoniae. Three categories of mutants were found among eight mutant plasmids examined in detail. Three mutant plasmids carried a single-base-pair (bp) change at position -12 or -14 relative to the nifH transcription start site. These mutations were located in a previously described consensus sequence found in the -10 to -15 region of nif promoters. Four of the mutant plasmids contain lesions considerably upstream from the start point of transcription. Two of these upstream mutations are identical 112-bp deletions of nucleotides -72 to -184, and two others are a single-bp change at position -136. The final plasmid does not contain a mutation within a 525-bp region which includes 289 bp upstream from the nifH ATG initiation codon and which extends 69 codons into the nifH gene. All eight of the mutant pSA30 plasmids failed to complement a chromosomal nifH mutation, suggesting that the mutations that block inhibition of nif expression also prevent transcription of the nifHDKY operon.

Structural relationships among Rhizobium meliloti symbiotic promoters

Symbiotic nitrogen fixation by Rhizobium meliloti requires the developmentally specific expression of certain bacterial genes. One set of these genes encodes the subunits of nitrogenase, the enzyme responsible for the reduction of atmospheric dinitrogen to ammonia, and another set consists of closely linked genes also essential for nitrogen fixation. Examination of promoter and probable regulatory regions for these gene sets has revealed extensive DNA sequence conservation for more than 160 bp upstream of the respective transcription start points. Three such promoter regions have been identified in the nitrogen fixation (nif) gene cluster of R. meliloti strain 102F34. Using one of these promoter regions as a hybridization probe, three additional sequences were found in the genome of this strain. The DNA of other R. meliloti strains and Rhizobium species were also examined for homology to the symbiotically regulated promoters of R. meliloti 102F34. DNA sequences homologous to these R. meliloti promoters were found among diverse rhizobia, and in at least some cases were associated with nif genes.

Chromosome transfer and R-prime plasmid formation mediated by plasmid pULB113 (RP4::mini-Mu) in Alcaligenes eutrophus CH34 and Pseudomonas fluorescens 6.2

Plasmid pULB113 (RP4::mini-Mu), which contains the mini-Mu transposon, promoted both homologous and heterologous gene transfer from Pseudomonas fluorescens 6.2 and Alcaligenes eutrophus CH34. Homologous gene transfer in P. fluorescens 6.2 and A. eutrophus CH34 occurred at a frequency of 10(-4) to 10(-5), and recombinants inherited unselected recessive markers, suggesting a process of chromosome mobilization. Loci involved in autotrophic growth were among those transferred in A. eutrophus. In heterospecific matings, markers were transferred from P. fluorescens to A. eutrophus, Salmonella typhimurium LT2, and Escherichia coli, from A. eutrophus to P. fluorescens, and from Erwinia carotovora subsp. chrysanthemi to A. eutrophus. Heterospecific matings resulted in the formation of R-prime plasmids at frequencies of 10(-7) to 10(-4) per transferred plasmid. When S. typhimurium was the recipient, we observed R-prime plasmids with both restriction-proficient and restriction-deficient strains, although restriction markedly affected the frequency of transfer of pULB113. R-prime plasmids were quite stable, but lost the transposed marker more easily in a rec+ background than in a recA background, suggesting excision of transposed material by reciprocal recombination between flanking copies of mini-Mu. R-prime plasmids could be transferred easily into different recipients and were used in complementation studies. PstI restriction digests of four R-prime plasmids carrying P. fluorescens 6.2 DNA showed a number of additional bands, suggesting that several genes were transposed together with the selected marker on the plasmid.

Activation of Klebsiella pneumoniae and Rhizobium meliloti nitrogenase promoters by gln (ntr) regulatory proteins

We have studied the expression, in different Escherichia coli gln (ntr) mutants, of fusions (constructed in vitro) of the nifHDK (nitrogenase) promoters from Klebsiella pneumoniae and Rhizobium meliloti to E. coli lacZ. Derepression of the K. pneumoniae nifH::lacZ fusion requires the glnF (ntrA) gene product in addition to the K. pneumoniae nifA gene product, indicating that regulation of the K. pneumoniae nif genes is more closely integrated with the overall nitrogen control system than previously demonstrated. Derepression of the R. meliloti nifH::lacZ fusion in E. coli by the K. pneumoniae nifA gene product (which we had previously shown) exhibits the same requirement for glnF. Derepression of the R. meliloti nifH::lacZ fusion, but not the K. pneumoniae nifH::lacZ fusion, can be mediated by the glnG (ntrC) gene product, suggesting that the gln regulatory genes might directly regulate the symbiotic nitrogen fixation genes in Rhizobium.

Promoters regulated by the glnG (ntrC) and nifA gene products share a heptameric consensus sequence in the -15 region

We have determined the nucleotide sequences of the Klebsiella pneumoniae nifL (regulation of N2 fixation genes) and the Escherichia coli glnA (glutamine synthetase) promoters. We compared these sequences with the published sequences of three other promoters that, like the nifL and glnA promoters, are activated by the general nitrogen regulators glnF (ntrA) and glnG (ntrC). The three promoters are the argTr (arginine transport) and dhuA (histidine transport) promoters of Salmonella typhimurium and the nifH (nitrogenase) promoter of Rhizobium meliloti. All five sequences (with at most one mismatch) contain the heptameric consensus sequence T-T-T-T-G-C-A. In the R. meliloti nifH and K. pneumoniae nifL promoters, in which the transcription initiation sites have been determined, the consensus sequence is situated in the -15 region. We recently reported that the K. pneumoniae nifA product, which activates nif genes, can substitute for the glnG (ntrC) product in activating promoters of several genes involved in nitrogen assimilation, including the nifL, the glnA, and the R. meliloti nifH promoters. It is likely that nifA also activates the S. typhimurium argTr and dhuA promoters. In contrast, the glnG product cannot substitute for the nifA product in the activation of the K. pneumoniae nifH (nitrogenase) promoter. Consistent with this latter observation, and supporting the conclusion that the T-T-T-T-G-C-A sequence is a regulatory site for glnG product activation, the K. pneumoniae nifH promoter (C-C-C-T-G-C-A) has only partial similarity with the T-T-T-T-G-C-A consensus sequence in the -15 region.

Activation of nif gene expression in Azotobacter by the nifA gene product of Klebsiella pneumoniae

Structural similarity of nitrogenase, the enzyme responsible for biological nitrogen fixation, from various diazotrophic bacteria has been shown by intergeneric biochemical complementation of component proteins in vitro, DNA and protein sequence analysis, and DNA hybridization between nif (nitrogen fixation) structural genes from Klebsiella pneumoniae and genomic sequences from other nitrogen-fixing bacteria. Despite nitrogenase homologies, little is known about similarities among nif regulatory mechanisms although repression of nitrogenase synthesis by NH4+ and O2 occurs in most diazotrophs. In K. pneumoniae, the ntr (gln) genes concerned with regulation of nitrogen metabolism control expression of the nifLA operon whose products act as repressor (nifL) and activator (nifA) of the seven other nif transcriptional units. Here we report that the nifA gene product of K. pneumoniae can activate expression of nif genes in both Azotobacter vinelandii and Azotobacter chroococcum, organisms whose aerobic physiology contrasts with that of the facultative K. pneumoniae.

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.

Regulation of nitrogen metabolism genes by nifA gene product in Klebsiella pneumoniae

The Klebsiella pneumoniae nifA gene product, which is known to activate expression of the nitrogen fixation (nif) structural genes, is shown here also to be able to substitute for the product of the gene glnG (ntrC) in the regulation of other nitrogen metabolism genes. An evolutionary relationship between the nifA and glnG genes is suggested.

Cloning and expression of a DNA fragment carrying a his nifA fusion and the nifBQ operon from a nif constitutive mutant of Klebsiella pneumoniae

From the nifc mutant plasmid pPC868, previously shown to carry a DNA duplication responsible for the Nifc phenotype, a 10 kb HindIII fragment was cloned into the multicopy vector pBR325. Restriction analysis of the resulting plasmids and in vitro deleted derivatives confirmed that the mutation was a fusion between his and nifLA. The order was hisG-hisD'-'nifL-nifA so that nifA was transcribed under the control of the his promoter and the nifL gene was altered. In addition the cloned fragment contained the adjacent nifBQ operon, and complementation data revealed that the nifA, nifB and hisG genes were expressed. Synthesis of nifA product under the transcription control of the his (or cat [CmR]) promoter enabled complementation of nifA and nifB mutations either in the absence or the presence of ammonia, but did not restore nitrogen fixation in a glnF mutant. Therefore, the nifA gene product requires glnF for its positive control function in a manner analogous to ntrC. Protein content analysis of minicells containing various multicopy nif plasmids confirmed the genetic organization mentioned above. A new polypeptide of 51,500 daltons was found whose synthesis was observed at 30 degrees C but not at 37 degrees C. According to the physical map, this protein could be the nifB gene product. Our results are in agreement with nifB transcription being under the control of a thermolabile nifA product. Moreover we obtained results suggesting that the presence of multiple copies of a functional nifB gene inhibited nitrogen fixation.

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.