General method, using Mu-Mud1 dilysogens, to determine the direction of transcription of and generate deletions in the glnA region of Escherichia coli

Possible role of glutamine synthetase of the prokaryotic type (GSI-like) in nitrogen signaling in Medicago truncatula

Genes containing domains related to glutamine synthetase of the prokaryotic type (GSI-like) are widespread in higher plants, but their function is currently unknown. To gain insights into the possible role of GSI-like proteins, we characterized the GSI-like gene family of Medicago truncatula and investigated the functionality of the encoded proteins. M. truncatula contains two-expressed GSI-like genes, MtGSIa and MtGSIb, encoding polypeptides of 454 and 453 amino acids, respectively. Heterologous complementation assays of a bacterial glnA mutant indicate that the proteins are not catalytically functional for glutamine synthesis. Gene expression was investigated by qRT-PCR and western blot analysis in different organs of the plant and under different nitrogen (N) regimes, revealing that both genes are preferentially expressed in roots and root nodules, and that their expression is influenced by the N-status of the plant. Analysis of transgenic plants expressing MtGSI-like-promoter-gusA fusion, indicate that the two genes are strongly expressed in the root pericycle, and interestingly, the expression is enhanced at the sites of nodule emergence being particularly strong in specific cells located in front of the protoxylem poles. Taken together, the results presented here support a role of GSI-like proteins in N sensing and/or signaling, probably operating at the interface between perception of the N-status and the developmental processes underlying both root nodule and lateral root formation. This study indicates that GSI-like genes may represent a novel class of molecular players of the N-mediated signaling events.

Control of AmtB-GlnK complex formation by intracellular levels of ATP, ADP, and 2-oxoglutarate

P(II) proteins are one of the most widespread families of signal transduction proteins in nature, being ubiquitous throughout bacteria, archaea, and plants. They play a major role in coordinating nitrogen metabolism by interacting with, and regulating the activities of, a variety of enzymes, transcription factors, and membrane transport proteins. The regulatory properties of P(II) proteins derive from their ability to bind three effectors: ATP, ADP, and 2-oxoglutarate. However, a clear model to integrate physiological changes with the consequential structural changes that mediate P(II) interaction with a target protein has so far not been developed. In this study, we analyzed the fluctuations in intracellular effector pools in Escherichia coli during association and dissociation of the P(II) protein GlnK with the ammonia channel AmtB. We determined that key features promoting AmtB-GlnK complex formation are the rapid drop in the 2-oxoglutarate pool upon ammonium influx and a simultaneous, but transient, change in the ATP/ADP ratio. We were also able to replicate AmtB-GlnK interactions in vitro using the same effector combinations that we observed in vivo. This comprehensive data set allows us to propose a model that explains the way in which interactions between GlnK and its effectors influence the conformation of GlnK and thereby regulate its interaction with AmtB.

Medicago truncatula contains a second gene encoding a plastid located glutamine synthetase exclusively expressed in developing seeds

BACKGROUND

Nitrogen is a crucial nutrient that is both essential and rate limiting for plant growth and seed production. Glutamine synthetase (GS), occupies a central position in nitrogen assimilation and recycling, justifying the extensive number of studies that have been dedicated to this enzyme from several plant sources. All plants species studied to date have been reported as containing a single, nuclear gene encoding a plastid located GS isoenzyme per haploid genome. This study reports the existence of a second nuclear gene encoding a plastid located GS in Medicago truncatula.

RESULTS

This study characterizes a new, second gene encoding a plastid located glutamine synthetase (GS2) in M. truncatula. The gene encodes a functional GS isoenzyme with unique kinetic properties, which is exclusively expressed in developing seeds. Based on molecular data and the assumption of a molecular clock, it is estimated that the gene arose from a duplication event that occurred about 10 My ago, after legume speciation and that duplicated sequences are also present in closely related species of the Vicioide subclade. Expression analysis by RT-PCR and western blot indicate that the gene is exclusively expressed in developing seeds and its expression is related to seed filling, suggesting a specific function of the enzyme associated to legume seed metabolism. Interestingly, the gene was found to be subjected to alternative splicing over the first intron, leading to the formation of two transcripts with similar open reading frames but varying 5' UTR lengths, due to retention of the first intron. To our knowledge, this is the first report of alternative splicing on a plant GS gene.

CONCLUSIONS

This study shows that Medicago truncatula contains an additional GS gene encoding a plastid located isoenzyme, which is functional and exclusively expressed during seed development. Legumes produce protein-rich seeds requiring high amounts of nitrogen, we postulate that this gene duplication represents a functional innovation of plastid located GS related to storage protein accumulation exclusive to legume seed metabolism.

A sigma54-dependent promoter in the regulatory region of the Escherichia coli rpoH gene

The Escherichia coli rpoH gene is transcribed from four known and differently regulated promoters: P1, P3, P4 and P5. This study demonstrates that the conserved consensus sequence of the sigma54 promoter in the regulatory region of the rpoH gene, described previously, is a functional promoter, P6. The evidence for this conclusion is: (i) the specific binding of the sigma54-RNAP holoenzyme to P6, (ii) the location of the transcription start site at the predicted position (C, 30 nt upstream of ATG) and (iii) the dependence of transcription on sigma54 and on an ATP-dependent activator. Nitrogen starvation, heat shock, ethanol and CCCP treatment did not activate transcription from P6 under the conditions examined. Two activators of sigma54 promoters, PspF and NtrC, were tested but neither of them acted specifically. Therefore, PspFDeltaHTH, a derivative of PspF, devoid of DNA binding capability but retaining its ATPase activity, was used for transcription in vitro, taking advantage of the relaxed specificity of ATP-dependent activators acting in solution. In experiments in vivo overexpression of PspFDeltaHTH from a plasmid was employed. Thus, the sigma54-dependent transcription capability of the P6 promoter was demonstrated both in vivo and in vitro, although the specific conditions inducing initiation of the transcription remain to be elucidated. The results clearly indicate that the closed sigma54-RNAP-promoter initiation complex was formed in vitro and in vivo and needed only an ATP-dependent activator to start transcription.

The expression ofnifBgene fromHerbaspirillum seropedicaeis dependent upon the NifA and RpoN proteins

The putative nifB promoter region of Herbaspirillum seropedicae contained two sequences homologous to NifA-binding site and a –24/–12 type promoter. A nifB::lacZ fusion was assayed in the backgrounds of both Escherichia coli and H. seropedicae. In E. coli, the expression of nifB::lacZ occurred only in the presence of functional rpoN and Klebsiella pneumoniae nifA genes. In addition, the integration host factor (IHF) stimulated the expression of the nifB::lacZ fusion in this background. In H. seropedicae, nifB expression occurred only in the absence of ammonium and under low levels of oxygen, and it was shown to be strictly dependent on NifA. DNA band shift experiments showed that purified K. pneumoniae RpoN and E. coli IHF proteins were capable of binding to the nifB promoter region, and in vivo dimethylsulfate footprinting showed that NifA binds to both NifA-binding sites. These results strongly suggest that the expression of the nifB promoter of H. seropedicae is dependent on the NifA and RpoN proteins and that the IHF protein stimulates NifA activation of nifB promoter.Key words: Herbaspirillum seropedicae, nif, nitrogen fixation, NifA, RpoN.

In vivo functional characterization of the Escherichia coli ammonium channel AmtB: evidence for metabolic coupling of AmtB to glutamine synthetase

The Escherichia coli AmtB protein is member of the ubiquitous Amt family of ammonium transporters. Using a variety of [14C]methylammonium-uptake assays in wild-type E. coli, together with amtB and glutamine synthetase (glnA) mutants, we have shown that the filtration method traditionally used to measure [14C]methylammonium uptake actually measures intracellular accumulation of methylglutamine and that the kinetic data deduced from such experiments refer to the activity of glutamine synthetase and not to AmtB. Furthermore, the marked difference between the K(m) values of glutamine synthetase calculated in vitro and those calculated in vivo from our data suggest that ammonium assimilation by glutamine synthetase is coupled to the function of AmtB. The use of a modified assay technique allows us to measure AmtB activity in vivo. In this way, we have examined the role that AmtB plays in ammonium/methylammonium transport, in the light of conflicting proposals with regard to both the mode of action of Amt proteins and their substrate, i.e. ammonia or ammonium. Our in vivo data suggest that AmtB acts as a slowly conducting channel for NH3 that is neither dependent on the membrane potential nor on ATP. Furthermore, studies on competition between ammonium and methylammonium suggest that AmtB has a binding site for NH4+ on the periplasmic face.

Expression of the plastid-located glutamine synthetase of Medicago truncatula. Accumulation of the precursor in root nodules reveals an in vivo control at the level of protein import into plastids

In this paper, we report the cloning and characterization of the plastid-located glutamine synthetase (GS) of Medicago truncatula Gaertn (MtGS2). A cDNA was isolated encoding a GS2 precursor polypeptide of 428 amino acids composing an N-terminal transit peptide of 49 amino acids. Expression analysis, by Westerns and by northern hybridization, revealed that MtGS2 is expressed in both photosynthetic and non-photosynthetic organs. Both transcripts and proteins of MtGS2 were detected in substantial amounts in root nodules, suggesting that the enzyme might be performing some important role in this organ. Surprisingly, about 40% of the plastid GS in nodules occurred in the non-processed precursor form (preGS2). This precursor was not detected in any other organ studied and moreover was not observed in non-fixing nodules. Cellular fractionation of nodule extracts revealed that preGS2 is associated with the plastids and that it is catalytically inactive. Immunogold electron microscopy revealed a frequent coincidence of GS with the plastid envelope. Taken together, these results suggest a nodule-specific accumulation of the GS2 precursor at the surface of the plastids in nitrogen-fixing nodules. These results may reflect a regulation of GS2 activity in relation to nitrogen fixation at the level of protein import into nodule plastids.

Expression of the nifA gene of Herbaspirillum seropedicae: role of the NtrC and NifA binding sites and of the -24/-12 promoter element

The nifA promoter of Herbaspirillum seropedicae contains potential NtrC, NifA and IHF binding sites together with a -12/-24 sigma(N)-dependent promoter. This region has now been investigated by deletion mutagenesis for the effect of NtrC and NifA on the expression of a nifA::lacZ fusion. A 5' end to the RNA was identified at position 641, 12 bp downstream from the -12/-24 promoter. Footprinting experiments showed that the G residues at positions -26 and -9 are hypermethylated, and that the region from -10 to +10 is partially melted under nitrogen-fixing conditions, confirming that this is the active nifA promoter. In H. seropedicae nifA expression from the sigma(N)-dependent promoter is repressed by fixed nitrogen but not by oxygen and is probably activated by the NtrC protein. NifA protein is apparently not essential for nifA expression but it can still bind the NifA upstream activating sequence.

Catabolism of phenylacetic acid in Escherichia coli. Characterization of a new aerobic hybrid pathway

The paa cluster of Escherichia coli W involved in the aerobic catabolism of phenylacetic acid (PA) has been cloned and sequenced. It was shown to map at min 31.0 of the chromosome at the right end of the mao region responsible for the transformation of 2-phenylethylamine into PA. The 14 paa genes are organized in three transcription units: paaZ and paaABCDEFGHIJK, encoding catabolic genes; and paaXY, containing the paaX regulatory gene. The paaK gene codes for a phenylacetyl-CoA ligase that catalyzes the activation of PA to phenylacetyl-CoA (PA-CoA). The paaABCDE gene products, which may constitute a multicomponent oxygenase, are involved in PA-CoA hydroxylation. The PaaZ protein appears to catalyze the third enzymatic step, with the paaFGHIJ gene products, which show significant similarity to fatty acid beta-oxidation enzymes, likely involved in further mineralization to Krebs cycle intermediates. Three promoters, Pz, Pa, and Px, driven the expression of genes paaZ, paaABCDEFGHIJK, and paaX, respectively, have been identified. The Pa promoter is negatively controlled by the paaX gene product. As PA-CoA is the true inducer, PaaX becomes the first regulator of an aromatic catabolic pathway that responds to a CoA derivative. The aerobic catabolism of PA in E. coli represents a novel hybrid pathway that could be a widespread way of PA catabolism in bacteria.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

The FixK2 protein is involved in regulation of symbiotic hydrogenase expression in Bradyrhizobium japonicum

The roles of the nitrogen fixation regulatory proteins NifA, FixK1, and FixK2 in the symbiotic regulation of hydrogenase structural gene expression in Bradyrhizobium japonicum have been investigated. Bacteroids from FixJ and FixK2 mutants have little or no hydrogenase activity, and extracts from these mutant bacteroids contain no hydrogenase protein. Bacteroids from a FixK1 mutant exhibit wild-type levels of hydrogenase activity. In beta-galactosidase transcriptional assays with NifA and FixK2 expression plasmids, the FixK2 protein induces transcription from the hup promoter to levels similar to those induced by HoxA, the transcriptional activator of free-living hydrogenase expression. The NifA protein does not activate transcription at the hydrogenase promoter. Therefore, FixK2 is involved in the transcriptional activation of symbiotic hydrogenase expression. By using beta-galactosidase transcriptional fusion constructs containing successive truncations of the hup promoter, the region of the hup promoter required for regulation by FixK2 was determined to be between 29 and 44 bp upstream of the transcription start site.

Modulation of the function of the signal receptor domain of XylR, a member of a family of prokaryotic enhancer-like positive regulators

The XylR protein controls expression from the Pseudomonas putida TOL plasmid upper pathway operon promoter (Pu) in response to aromatic effectors. XylR-dependent stimulation of transcription from a Pu::lacZ fusion shows different induction kinetics with different effectors. With toluene, activation followed a hyperbolic curve with an apparent K of 0.95 mM and a maximum beta-galactosidase activity of 2,550 Miller units. With o-nitrotoluene, in contrast, activation followed a sigmoidal curve with an apparent K of 0.55 mM and a Hill coefficient of 2.65. m-Nitrotoluene kept the XylR regulator in an inactive transcriptional form. Therefore, upon binding of an effector, the substituent on the aromatic ring leads to productive or unproductive XylR forms. The different transcriptional states of the XylR regulator are substantiated by XylR mutants. XylRE172K is a mutant regulator that is able to stimulate transcription from the Pu promoter in the presence of m-nitrotoluene; however, its response to m-aminotoluene was negligible, in contrast with the wild-type regulator. These results illustrate the importance of the electrostatic interactions in effector recognition and in the stabilization of productive and unproductive forms by the regulator upon aromatic binding. XylRD135N and XylRD135Q are mutant regulators that are able to stimulate transcription from Pu in the absence of effectors, whereas substitution of Glu for Asp135 in XylRD135E resulted in a mutant whose ability to recognize effectors was severely impaired. Therefore, the conformation of mutant XylRD135Q as well as XylRD135N seemed to mimic that of the wild-type regulator when effector binding occurred, whereas mutant XylRD135E seemed to be blocked in a conformation similar to that of wild-type XylR and XylRE172K upon binding to an inhibitor molecule such as m-nitrotoluene or m-aminotoluene.

Heteromeric assembly of the cytosolic glutamine synthetase polypeptides of Medicago truncatula: complementation of a glnA Escherichia coli mutant with a plant domain-swapped enzyme

We have cloned and sequenced the cDNAs corresponding to the two cytosolic glutamine synthetase (GS) polypeptides (a and b) of Medicago truncatula. Using these two cDNAs we have prepared a construct encoding the N-terminal domain of b and the C-terminal domain of a in order to produce a domain-swapped polypeptide which should assemble to give an enzyme containing chimeric active sites. Both the native and the domain-swapped enzymes were expressed in Escherichia coli where they were catalytically and physiologically active as they were able to rescue a glnA deletion mutant. The expressed polypeptides were of the correct size and the isoenzymes behaved similarly to their native homologues on ion-exchange chromatography. We have found slight differences in the kinetic properties of the purified enzymes and in the modulation of their activities by several putative cellular effectors. In vitro dissociation of the purified a and b homo-octamers, followed by reassociation, showed that the subunits are able to self-assemble, perhaps randomly, to form heteromeric isoenzymes. Moreover, heteromeric isoenzymes occur in the plant as revealed by studies on the GS isoenzymes of nodules, roots, stems and stipules.

Evidence for two possible glnB-type genes in Herbaspirillum seropedicae

Two glnB-like genes have been isolated from Herbaspirillum seropedicae by complementation of the Klebsiella pneumoniae glnB502 mutant for growth on nitrate. One of these glnB-like genes has been sequenced and shows strong identity with GlnB proteins derived from other organisms. A Tn5-20 mutation of this glnB was Nif negative.

Molecular characterization of the 4-hydroxyphenylacetate catabolic pathway of Escherichia coli W: engineering a mobile aromatic degradative cluster

We have determined and analyzed the nucleic acid sequence of a 14,855-bp region that contains the complete gene cluster encoding the 4-hydroxyphenylacetic acid (4-HPA) degradative pathway of Escherichia coli W (ATCC 11105). This catabolic pathway is composed by 11 genes, i.e., 8 enzyme-encoding genes distributed in two putative operons, hpaBC (4-HPA hydroxylase operon) and hpaGEDFHI (meta-cleavage operon); 2 regulatory genes, hpaR and hpaA; and the gene, hpaX, that encodes a protein related to the superfamily of transmembrane facilitators and appears to be cotranscribed with hpaA. Although comparisons with other aromatic catabolic pathways revealed interesting similarities, some of the genes did not present any similarity to their corresponding counterparts in other pathways, suggesting different evolutionary origins. The cluster is flanked by two genes homologous to the estA (carbon starvation protein) and tsr (serine chemoreceptor) genes of E. coli K-12. A detailed genetic analysis of this region has provided a singular example of how E. coli becomes adapted to novel nutritional sources by the recruitment of a catabolic cassette. Furthermore, the presence of the pac gene in the proximity of the 4-HPA cluster suggests that the penicillin G acylase was a recent acquisition to improve the ability of E. coli W to metabolize a wider range of substrates, enhancing its catabolic versatility. Five repetitive extragenic palindromic sequences that might be involved in transcriptional regulation were found within the cluster. The complete 4-HPA cluster was cloned in plasmid and transposon cloning vectors that were used to engineer E. coli K-12 strains able to grow on 4-HPA. We report here also the in vitro design of new biodegradative capabilities through the construction of a transposable cassette containing the wide substrate range 4-HPA hydroxylase, in order to expand the ortho-cleavage pathway of Pseudomonas putida KT2442 and allow the new recombinant strain to use phenol as the only carbon source.

NtrBC-dependent expression from the Rhizobium meliloti dctA promoter in Escherichia coli

Effects of the two-component sensor-regulator pairs DctBD and NtrBC upon the expression of a dctA::phoA fusion from Rhizobium meliloti were determined under excess and limiting nitrogen concentrations in Escherichia coli. Results indicated that NtrBC affected transcription from the dctA promoter on a number of regulatory levels and under different physiological conditions in the heterologous host. However, NtrBC-dependent cross-talk was not observed in free-living R. meliloti under the conditions tested. Comparisons of the predicted amino acid sequences of DctD and NtrC from various sources indicated a specific region of the NtrC from rhizobia, which may have diverged from a consensus NtrC/DctD sequence to minimise interference between the two component systems, NtrBC and DctBD.

Single amino acids changes in the signal receptor domain of XylR resulted in mutants that stimulate transcription in the absence of effectors

The XylR protein positively controls expression from the Pseudomonas putida TOL plasmid sigma 54-dependent "upper" pathway operon promoter (Pu) and the xylS gene promoter (Ps), in response to the presence of aromatic effectors. Two mutant XylR regulators able to stimulate transcription from Pu and Ps in the absence of effectors were isolated. These mutants exhibited single point mutations, namely Asp135-->Asn and Pro85-->Ser. Both mutations are located in the amino termini domain of XylR, which is thought to be responsible for interactions with effectors. The effector profile of XylRP85S was similar to that of wild-type XylR protein; however, XylRD135N exhibited an altered pattern of effector recognition: with m-nitrotoluene it stimulated transcription from the Pu promoter above the high basal level, whereas this nitroarene inhibited the wild-type regulator. Previous work (Delgado, A., and Ramos, J.L. (1994) J. Biol. Chem. 269, 8059-8062) showed that residue 172 was involved in effector interactions, as mutant XylRE172K also recognized m-nitrotoluene. However, double mutant XylR135N/E172K did not stimulate transcription in the absence of effector, but retained the ability to stimulate transcription with m-nitrotoluene. Transcription mediated by XylRD135N and XylRP85S from Pu::lacZ was analyzed in detail. Like the wild-type regulator, XylRD135N and XylRP85S required sigma 54 for full transcription activation, but in contrast with the wild-type regulator, XylRD135N, but not XylRP85S, stimulated transcription from Pu in the absence of the integration host factor protein. XylRD135N, also in contrast with XylR and XylRP85S, mediated transcription from a mutant Pu promoter that lacked one of the upstream regulator binding sites (delta UAS1), but not when both upstream regulator binding sites were deleted. The level of autoregulation of XylRD135N was at least 2-fold higher than that found with the wild-type XylR regulator and the mutant XylRP85S.

Oxygen sensitivity and metal ion-dependent transcriptional activation by NIFA protein from Rhizobium leguminosarum biovar trifolii

The NIFA protein from Rhizobium leguminosarum biovar trifolii (R. trifolii) strain ANU843 lacks an N-terminal domain present in homologous NIFA proteins from other diazotrophs. The R. trifolii nifA gene product is unstable when expressed in Escherichia coli under both aerobic and microaerobic conditions. Stability is increased by fusion of additional amino acids to the N-terminus of the protein or by expression of nifA in sno mutant (presumed protease deficient) strains of E. coli. Transcriptional activation in vivo by R. trifolii NIFA decreases under aerobic growth conditions, or when cultures are depleted of metal ions. In sno mutant strains this decrease in activity reflects a loss of specific activity rather than proteolytic degradation, implying that R. trifolii NIFA requires metal ions for activity and is oxygen sensitive. The addition of 30 amino acids to the amino-terminus of R. trifoli NIFA results in an oxygen-tolerant protein, with metal ion-dependent activity. Metal ions are therefore not only required for oxygen sensing by R. trifolii NIFA but may play an additional role in determining NIFA structure or activity.

A counterselectable pACYC184-based lacZ alpha-complementing plasmid vector with novel multiple cloning sites; construction of chromosomal deletions in Klebsiella pneumoniae

We have constructed a series of small, chloramphenicol-resistance-encoding, lacZ alpha-complementing vectors with novel multiple cloning sites, based on the pACYC184 replicon. The sacB gene of Bacillus subtilis, which is lethal to Gram- organisms in the presence of sucrose, was cloned into one of these, giving the counterselectable vector pSG335. This was used to substitute a streptomycin-resistance-encoding cassette for the ntrBC genes in the Klebsiella pneumoniae chromosome.

Characterisation of mutations in the Klebsiella pneumoniae nitrogen fixation regulatory gene nifL which impair oxygen regulation

The nifL gene product of Klebsiella pneumoniae inhibits the activity of the positive activator protein NifA in response to increased levels either of fixed nitrogen or of oxygen in the medium. In order to demonstrate that the responses to these two effectors are discrete we have subjected nifL to hydroxylamine mutagenesis and isolated nifL mutants that are impaired in their ability to respond to oxygen but not to fixed nitrogen. Two such mutations were sequenced and shown to be single base pair changes located in different parts of nifL. The amino acid sequence of NifL shows limited homology to the histidine protein kinases which comprise the sensing component of bacterial two-component regulatory systems. In the light of the location of one of the oxygen-insensitive mutations (Leu294Phe) we have reassessed this homology and we suggest that the Gln273-Leu317 region of NifL may facilitate interactions between NifL and NifA.

Cloning, heterologous expression, and sequencing of the Proteus vulgaris glnAntrBC operon and implications of nitrogen control on heterologous urease expression

The glnAntrBC operon of Proteus vulgaris was cloned and heterologously expressed in Escherichia coli. The nucleotide sequence was determined. An open reading frame of 1407 bp was identified as the glnA gene and the deduced amino acid sequence showed 82% identity with the E. coli glutamine synthetase protein. Heterologous expression of the glnA gene in E. coli restored glutamine synthetase (GS) activity in a GS-negative mutant and a 52 kDa protein was detected and addressed as the GS subunit of P. vulgaris. Adjacent to the glnA gene the regulatory genes ntrB and ntrC were identified. Their coding regions comprised 1053 and 1452 bp, respectively, and the deduced gene products NRII (NtrB) and NRI (NtrC) shared 72% identity with the corresponding E. coli proteins. Heterologous expression in E. coli revealed only a 54 kDa protein which was shown to be NRI. NRII was not detectable using the methods employed.

A defined amino acid exchange close to the putative nucleotide binding site is responsible for an oxygen-tolerant variant of the Rhizobium meliloti NifA protein

In Rhizobium meliloti the NifA protein plays a central role in the expression of genes involved in nitrogen fixation. The R. meliloti NifA protein has been found to be oxygen sensitive and therefore acts as a transcriptional activator only under microaerobic conditions. In order to generate oxygen-tolerant variants of the NifA protein a plasmid carrying the R. meliloti nifA gene was mutagenized in vitro with hydroxylamine. About 70 mutated nifA genes were isolated which mediated up to 12-fold increased NifA activity at high oxygen concentrations. A cloning procedure involving the combination of DNA fragments from mutated and wild-type nifA genes allowed mapping of the mutation sites within the central part of the nifA gene. For 17 mutated nifA genes the exact mutation sites were determined by DNA sequence analysis. It was found that all 17 mutated nifA genes carried identical guanosine--adenosine mutations resulting in a methionine--isoleucine exchange (M217I) near the putative nucleotide binding site within the central domain. Secondary structure predictions indicated that the conformation of the putative nucleotide binding site may be altered in the oxygen-tolerant NifA proteins. A model is proposed which assumes that at high oxygen concentrations the loss of activity of the R. meliloti NifA protein is due to a conformational change in the nucleotide binding site that may abolish binding or hydrolysis of the nucleotide. Such a conformational change may be blocked in the oxygen-tolerant NifA protein, thus allowing interaction with the nucleotide at high oxygen concentrations.

Central domain of the positive control protein NifA and its role in transcriptional activation

The positive control protein NifA of Klebsiella pneumoniae activates transcription by RNA polymerase containing sigma 54 by catalysing open promoter complex formation. We show that the integrity of the putative ATP-binding pocket in the central domain of NifA is necessary for the positive control function of NifA, but is not required for DNA-binding or recognition of NifA by NifL. The inactive mutant NifA proteins are trans dominant to wild-type NifA and are unable to catalyse formation of open promoter complexes irrespective of whether a closed promoter complex at the nifH promoter has preformed. Formation of the closed complex results in a DNA structural distortion adjacent to the DNA region melted in the open promoter complex. This distortion lies at the leading edge of the E sigma 54 footprint. Although unable to catalyse open complex formation, some mutant NifAs altered the chemical reactivity of the distorted base-pair indicating that they retain the ability to recognize the closed promoter complex. The activation phenotype of partially active NifA molecules was sensitive to promoter sequences known to influence closed complex formation, indicating differences in (1) the susceptibility of the closed complexes towards activation and (2) their requirements for NifA during activation.

Upstream binding sequences of the XylR activator protein and integration host factor in the xylS gene promoter region of the Pseudomonas TOL plasmid

The xylR and xylS genes, which encode the positive regulators of the TOL plasmid catabolic pathways, are adjacent genes on the TOL plasmid and are transcribed from divergent promoters. Transcription from the xylS gene promoter, Ps, is positively regulated by effector-activated XylR protein and requires the specific RNA polymerase sigma 54 subunit (RpoN). Deletions and point mutations in the Ps upstream region localized the site of XylR interaction to the region between -133 bp and -207 bp (with respect to the transcriptional start of the xylS messenger), which contains an inverted sequence repeat largely homologous to the motif recognised by XylR in the XylR-regulated 'upper' catabolic pathway promoter, Pu. Gel retardation experiments showed binding of IHF to the Ps promoter region. Corresponding sequences showing good homology to the IHF-binding consensus were identified close to the Ps Promoter (between -35 bp and -47 bp, Ps proximal site) and further upstream overlapping the XylR recognition sequence (Ps distal site). In the latter case IHF recognition motifs were found well conserved on both strands at nearly the same position (between -140 bp and -152 bp on the upper and between -141 bp and -153 bp on the lower strand). Expression from Ps, either under inducing or non-inducing conditions, was, however, only slightly influenced by the absence of IHF in an IHF-deficient mutant and thus activation of Ps, like that of other sigma 54-dependent promoters which are rich in Ts, does not absolutely require IHF protein.

Organization and function of binding sites for the transcriptional activator NifA in the Klebsiella pneumoniae nifE and nifU promoters

The interaction of the Klebsiella pneumoniae NifA protein, a sigma 54-dependent activator, with the nifE and nifU promoters was analysed. At these promoters NifA established contacts in addition to those predicted by the minimal formulation NifA binding site (5'-TGT-N10-ACA). The positions of the contacts indicate that bound NifA molecules could assemble to form an oligomer. At both promoters contacts with NifA are made predominantly on one face of the DNA helix, and all contacts appear necessary for full activation by NifA. The close contacts made by NifA appear to be made by the DNA-binding domain of NifA. This domain shows specific DNA-binding activity in vitro. The binding of NifA to one site in the nifU promoter depends upon occupancy of additional upstream sequences by NifA. At the nifE promoter NifA binds adjacent to an integration host factor (IHF) binding site, but in contrast to results obtained with the nifU promoter IHF does not diminish nifE promoter occupancy by NifA. The IHF requirement for efficient in vivo activation of the nifU promoter by NifA was greater than that of the nifE promoter. Accordingly, the affinity of IHF for the nifU promoter is higher than for the nifE promoter. Amongst promoters utilizing the sigma 54 holoenzyme, the nifE promoter appears somewhat atypical in having the activator bound at around position -74 rather than the usual 100 base-pairs or more upstream from the transcription start site.

Molecular analysis of the Azotobacter vinelandii glnA gene encoding glutamine synthetase

The gene encoding glutamine synthetase (GS), glnA, was cloned from Azotobacter vinelandii on a 6-kb EcoRI fragment that also carries the ntrBC genes. The DNA sequence of 1,952 bp including the GS-coding region was determined. An open reading frame of 467 amino acids indicated a gene product of Mr 51,747. Transcription of glnA occurred from a C residue located 32 bases upstream of an ATG considered to be the initiator codon because (i) it had a nearby potential ribosome-binding site and (ii) an open reading frame translated from this site indicated good N-terminal homology to 10 other procaryotic GSs. Sequences similar to the consensus RNA polymerase recognition sites at -10 and -35 were present at the appropriate distance upstream of the transcription initiation site. As expected from earlier genetic studies indicating that expression of A. vinelandii glnA did not depend on the rpoN (ntrA; sigma 54) gene product, no sigma 54 recognition sequences were present, nor was there significant regulation of glnA expression by fixed nitrogen. Repeated attempts to construct glutamine auxotrophs by recombination of glnA insertion mutations were unsuccessful, Although the mutated DNA could be found by hybridization experiments in drug-resistant A. vinelandii transformants, the wild-type glnA region was always present. These results suggest that glnA mutations are lethal in A. vinelandii. In [14C]glutamine uptake experiments, very little glutamine was incorporated into cells, suggesting that glutamine auxotrophs are nonviable because they cannot be supplied with sufficient glutamine to support growth.

Expression of three plant glutamine synthetase cDNA in Escherichia coli. Formation of catalytically active isoenzymes, and complementation of a glnA mutant

Three cDNA clones encoding the closely related glutamine synthetase (GS) alpha, beta and gamma polypeptides of Phaseolus vulgaris (French bean) were recombinantly expressed in Escherichia coli. The GS expression plasmids correctly synthesised the recombinant alpha, beta and gamma polypeptides which then assembled into catalytically active homo-octameric isoenzymes. These isoenzymes behaved similarly to their native homologues on ion-exchange and gel-filtration chromatography. Furthermore, the alpha and gamma isoenzymes complemented a GS(glnA)-deficient mutant, thus demonstrating their physiological activity in E. coli. Differences were observed between the three recombinant GS plasmids in their quantitative expression of the GS polypeptides and their ability to complement the E. coli mutant. These differences were correlated to the degree of solubility of the polypeptide, which was observed to be dependent on the temperature of expression. The production of active GS isoenzymes in E. coli facilitates the isolation and characterisation of the individual P. vulgaris homo-octameric GS isoenzymes.

Activation of the Klebsiella pneumoniae nifU promoter: identification of multiple and overlapping upstream NifA binding sites

The Klebsiella pneumoniae nifU promoter is positively controlled by the NifA protein and requires a form of RNA polymerase holoenzyme containing the rpoN encoded sigma factor, sigma 54. Occupancy of the K. pneumoniae nifU promoter by NifA was examined using in vivo dimethyl sulphate footprinting. Three binding sites for NifA (Upstream Activator Sequences, UASs 1, 2 and 3) located at -125, -116 and -72 were identified which conform to the UAS consensus sequence TGT-N10-ACA. An additional NifA binding site was identified at position -90. The UASs located at -125 (UAS1) and -116 (UAS2) overlap and do not appear to bind NifA as independent sites. They may represent a NifA binding site interacting with two NifA dimers. UAS3 is located at -72, and abuts a binding site for integration host factor (IHF) and is not normally highly occupied by NifA. In the absence of IHF UAS3 showed increased occupancy by NifA. Mutational and footprinting analysis of the three UASs indicates (1) IHF and NifA can compete for binding and that this competition influences the level of expression from the nifU promoter (2) that UAS2 is a principle sequence of the UAS 1,2 region required for activation and (3) that none of the NifA binding sites interacts with NifA independently. In vivo KMnO4 footprinting demonstrated that NifA catalyses open complex formation at the nifU promoter. IHF was required for maximal expression from the nifU and nifH promoters in Escherichia coli, and for the establishment of a Nif+ phenotype in E. coli from the nif plasmid pRD1.

The Rhizobium meliloti fdxN gene encoding a ferredoxin-like protein is necessary for nitrogen fixation and is cotranscribed with nifA and nifB

Sequencing of the Rhizobium meliloti DNA region downstream of nifA revealed the existence of nifB, fdxN and ORF3. The molecular weight of the fdxN protein (Mr 6830) and the distribution of cysteine residues in its deduced amino acid sequence is typical for low molecular weight bacterial ferredoxins. Interposon insertion and plasmid integration mutagenesis demonstrated that FdxN is essential for nitrogen fixation in R. meliloti, whereas the predicted translation product of ORF3 (Mr 8708) is not necessary for this process. In contrast, ferredoxin-like proteins, which are encoded by nifB-associated genes, are not required for nitrogen fixation in all other organisms analysed so far. Plasmid integration mutagenesis additionally revealed that nifA, nifB and fdxN form one transcriptional unit. This result was confirmed by complementation analysis of polar interposon insertion mutants of nifA, nifB and fdxN and by complementation of a non-polar nifA deletion mutant. A DNA sequence resembling a typical nif consensus promoter, which is preceded by two putative NifA-binding sites, is located in front of nifB. This nifB promoter can be activated in Escherichia coli by the nifA gene product of Klebsiella pneumoniae to the same level as that of the R. meliloti nifH promoter. In contrast, R. meliloti NifA stimulates the nifH promoter more efficiently than the nifB promoter. This low-level activation of the nifB promoter may be the reason why transcription of nifB and fdxN is initiated primarily at a promoter in front of nifA.

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.

Control of bacterial alkaline phosphatase synthesis and variation in an Escherichia coli K-12 phoR mutant by adenyl cyclase, the cyclic AMP receptor protein, and the phoM operon

Mutant phoR cells show a clonal variation phenotype with respect to bacterial alkaline phosphatase (BAP) synthesis. BAP clonal variation is characterized by an alternation between a Bap+ and Bap- phenotype. The switching is regulated by the phoM operon and the presence of glucose; the pho-510 mutant form of the phoM operon abolishes both BAP clonal variation and the effect of glucose (B.L. Wanner, J. Bacteriol. 169:900-903, 1987). In this paper we show that a mutation of the adenyl cyclase (cya) and the cyclic AMP receptor protein (crp) gene also abolish BAP clonal variation; either simultaneously reduces the amount of BAP made in phoR mutants. Also, the pho-510 mutation is epistatic; it increases BAP synthesis in delta cya phoR and delta crp phoR mutants. These data are consistent with the wild-type phoM operon having a negative, as well as a positive, regulatory role in gene expression. Furthermore, the data suggest that adenyl cyclase and Crp indirectly regulate BAP synthesis in a phoR mutant via an interaction with the phoM operon or its gene products. However, phoM operon expression was unaffected when tested with phoM operon lacZ transcriptional fusions. In addition, the switching Bap phenotype was not associated with an alternation in phoM operon expression.

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.

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.

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.

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.

Polarity in the glnA operon: suppression of the reg- phenotype by rho mutations

To determine the ability of mutations in glnA, the gene for glutamine synthetase (GS), to regulate nitrogen assimilatory enzymes, we assayed histidase and GS in 34 glnA (Gln(-)) strains. Twenty-five glnA mutants were RegC, synthesizing high levels of histidase regardless of the availability of nitrogen, and nine were Reg(-), synthesizing low levels of histidase in medium containing either limiting or excess ammonia. rho mutations were introduced into strains containing glnA point mutations or insertions in glnA, glnL, glnG, or glnF. The Reg(-) phenotype of strains with glnA point mutations, but not those with glnA or glnF insertions, was altered by the presence of rho, suggesting that glnA (Reg(-)) mutations are polar and exert their phenotype by decreasing expression of glnL and glnG. Consistent with this view, no GS protein was detected by two-dimensional gel electrophoresis in glnA (Reg(-)) rho(+) or glnA (Reg(-)) rho double mutants, whereas GS protein was detected in cells of 10 of 11 glnA (RegC) strains. Since glnA (Reg(-)) rho double mutants synthesize constitutive levels of histidase, GS protein is not necessary for full expression of histidase. Mu d1 insertions in glnL, but not those in glnG, responded to the presence of a rho allele, presumably owing to elevated transcription into glnG from the Mu d1 prophage. Our results suggest that glnA (Reg(-)) alleles are polar mutations, and a rho-dependent termination site down-stream is postulated as the basis for the polar phenomenon. The data also indicate that, under some circumstances, a significant portion of glnL and glnG transcription is initiated at the glnA promoter.

Fine-structure deletion map and complementation analysis of the glnA-glnL-glnG region in Escherichia coli

A total of 399 independent mutants of Escherichia coli were obtained which have point and insertion mutations in the glnA region. Mutants isolated included Gln- and Reg- strains (unable to utilize arginine as a nitrogen source). Mutations were mapped with 73 deletion-containing derivatives of a lambda gln phage. Complementation analysis was performed with lambda gln derivatives containing point mutations which conferred a Gln- or Reg- phenotype. Deletion mapping and complementation analysis assigned 104 mutations in 24 deletion intervals to glnA. Mutations in Reg- strains were assigned to two genes, glnL and glnG. glnL contained 131 mutations in 12 deletion intervals, and glnG contained 164 mutations in 10 deletion intervals. The gene order is glnA-glnL-glnG, transcribed from left to right. Polarity of insertion mutations indicates that glnL and glnG form from left to right. Polarity of insertion mutations indicates that glnL and glnG form an operon. Complementation analysis of glnA insertion mutations with glnL and glnG mutations showed polarity of glnA onto most glnL and glnG alleles, suggesting that transcription of glnA may proceed into the glnL-glnG operon. All mutations analyzed in glnA conferred a Gln- phenotype. However, we also found that over half of the Gln- strains isolated ater chemical mutagenesis contained point mutations in glnG. Mutants which synthesized a high level of glutamine synthetase in the presence of ammonia (GlnC phenotype) were selected as revertants of a strain with a Tn10 insertion in glnD and were mapped with chromosomal deletions. Results indicate that mutations in 12 and 15 examined strains clearly map outside of glnA, probably in glnL.