Mutational analysis of upstream sequences required for transcriptional activation of the Klebsiella pneumoniae nifH promoter

Cloning and characterization of nif structural and regulatory genes in the purple sulfur bacterium, Halorhodospira halophila

Halorhodospira halophila is a halophilic photosynthetic bacterium classified as a purple sulfur bacterium. We found that H. halophila generates hydrogen gas during photoautotrophic growth as a byproduct of a nitrogenase reaction. In order to consider the applied possibilities of this photobiological hydrogen generation, we cloned and characterized the structural and regulatory genes encoding the nitrogenase, nifH, nifD and nifA, from H. halophila. This is the first description of the nif genes for a purple sulfur bacterium. The amino-acid sequences of NifH and NifD indicated that these proteins are an Fe protein and a part of a MoFe protein, respectively. The important residues are conserved completely. The sequence upstream from the nifH region and sequence similarities of nifH and nifD with those of the other organisms suggest that the regulatory system might be a NifL-NifA system; however, H. halophila lacks nifL. The amino-acid sequence of H. halophila NifA is closer to that of the NifA of the NifL-NifA system than to that of NifA without NifL. H. halophila NifA does not conserve either the residue that interacts with NifL or the important residues involved in NifL-independent regulation. These results suggest the existence of yet another regulatory system, and that the development of functional systems and their molecular counterparts are not necessarily correlated throughout evolution. All of these Nif proteins of H. halophila possess an excess of acidic residues, which acts as a salt-resistant mechanism.

Secondary structure and DNA binding by the C-terminal domain of the transcriptional activator NifA from Klebsiella pneumoniae

The NifA protein of Klebsiella pneumoniae is required for transcriptional activation of all nitrogen fixation (nif) operons except the regulatory nifLA genes. At these operons, NifA binds to an upstream activator sequence (UAS), with the consensus TGT-N(10)-ACA, via a C-terminal DNA-binding domain (CTD). Binding of the activator to this upstream enhancer-like sequence allows NifA to interact with RNA polymerase containing the alternative sigma factor, sigma(54). The isolated NifA CTD is monomeric and binds specifically to DNA in vitro as shown by DNase I footprinting. Heteronuclear 3D NMR experiments have been used to assign the signals from the protein backbone. Three alpha-helices have been identified, based on secondary chemical shifts and medium range Halpha(i)-NH(i)( + 1), and NH(i)-NH(i)( + 1) NOEs. On addition of DNA containing a half-site UAS, several changes are observed in the NMR spectra, allowing the identification of residues that are most likely to interact with DNA. These occur in the final two helices of the protein, directly confirming that DNA binding is mediated by a helix-turn-helix motif.

Mutagenesis and functional characterization of the glnB, glnA, and nifA genes from the photosynthetic bacterium Rhodospirillum rubrum

Nitrogen fixation is tightly regulated in Rhodospirillum rubrum at two different levels: transcriptional regulation of nif expression and posttranslational regulation of dinitrogenase reductase by reversible ADP-ribosylation catalyzed by the DRAT-DRAG (dinitrogenase reductase ADP-ribosyltransferase-dinitrogenase reductase-activating glycohydrolase) system. We report here the characterization of glnB, glnA, and nifA mutants and studies of their relationship to the regulation of nitrogen fixation. Two mutants which affect glnB (structural gene for P(II)) were constructed. While P(II)-Y51F showed a lower nitrogenase activity than that of wild type, a P(II) deletion mutant showed very little nif expression. This effect of P(II) on nif expression is apparently the result of a requirement of P(II) for NifA activation, whose activity is regulated by NH(4)(+) in R. rubrum. The modification of glutamine synthetase (GS) in these glnB mutants appears to be similar to that seen in wild type, suggesting that a paralog of P(II) might exist in R. rubrum and regulate the modification of GS. P(II) also appears to be involved in the regulation of DRAT activity, since an altered response to NH(4)(+) was found in a mutant expressing P(II)-Y51F. The adenylylation of GS plays no significant role in nif expression or the ADP-ribosylation of dinitrogenase reductase, since a mutant expressing GS-Y398F showed normal nitrogenase activity and normal modification of dinitrogenase reductase in response to NH(4)(+) and darkness treatments.

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.

Hydrogenase genes from Rhizobium leguminosarum bv. viciae are controlled by the nitrogen fixation regulatory protein nifA

Rhizobium leguminosarum bv. viciae expresses an uptake hydrogenase in symbiosis with peas (Pisum sativum) but, unlike all other characterized hydrogen-oxidizing bacteria, cannot express it in free-living conditions. The hydrogenase-specific transcriptional activator gene hoxA described in other species was shown to have been inactivated in R. leguminosarum by accumulation of frameshift and deletion mutations. Symbiotic transcription of hydrogenase structural genes hupSL originates from a -24/-12 type promoter (hupSp). A regulatory region located in the -173 to -88 region was essential for promoter activity in R. leguminosarum. Activation of hupSp was observed in Klebsiella pneumoniae and Escherichia coli cells expressing the K. pneumoniae nitrogen fixation regulator NifA, and in E. coli cells expressing R. meliloti NifA. This activation required direct interaction of NifA with the essential -173 to -88 regulatory region. However, no sequences resembling known NifA-binding sites were found in or around this region. NifA-dependent activation was also observed in R. etli bean bacteroids. NifA-dependent hupSp activity in heterologous hosts was also absolutely dependent on the RpoN sigma-factor and on integration host factor. Proteins immunologically related to integration host factor were identified in R. leguminosarum. The data suggest that hupSp is structurally and functionally similar to nitrogen fixation promoters. The requirement to coordinate nitrogenase-dependent H2 production and H2 oxidation in nodules might be the reason for the loss of HoxA in R. leguminosarum and the concomitant NifA control of hup gene expression. This evolutionary acquired control would ensure regulated synthesis of uptake hydrogenase in the most common H2-rich environment for rhizobia, the legume nodule.

Genetic regulation of nitrogen fixation in rhizobia

This review presents a comparison between the complex genetic regulatory networks that control nitrogen fixation in three representative rhizobial species, Rhizobium meliloti, Bradyrhizobium japonicum, and Azorhizobium caulinodans. Transcription of nitrogen fixation genes (nif and fix genes) in these bacteria is induced primarily by low-oxygen conditions. Low-oxygen sensing and transmission of this signal to the level of nif and fix gene expression involve at least five regulatory proteins, FixL, FixJ, FixK, NifA, and RpoN (sigma 54). The characteristic features of these proteins and their functions within species-specific regulatory pathways are described. Oxygen interferes with the activities of two transcriptional activators, FixJ and NifA. FixJ activity is modulated via phosphorylation-dephosphorylation by the cognate sensor hemoprotein FixL. In addition to the oxygen responsiveness of the NifA protein, synthesis of NifA is oxygen regulated at the level of transcription. This type of control includes FixLJ in R. meliloti and FixLJ-FixK in A. caulinodans or is brought about by autoregulation in B. japonicum. NifA, in concert with sigma 54 RNA polymerase, activates transcription from -24/-12-type promoters associated with nif and fix genes and additional genes that are not directly involved in nitrogen fixation. The FixK proteins constitute a subgroup of the Crp-Fnr family of bacterial regulators. Although the involvement of FixLJ and FixK in nifA regulation is remarkably different in the three rhizobial species discussed here, they constitute a regulatory cascade that uniformly controls the expression of genes (fixNOQP) encoding a distinct cytochrome oxidase complex probably required for bacterial respiration under low-oxygen conditions. In B. japonicum, the FixLJ-FixK cascade also controls genes for nitrate respiration and for one of two sigma 54 proteins.

The Klebsiella pneumoniae nifJ promoter: analysis of promoter elements regulating activation by the NifA promoter

The nifJ and nifH promoters of Klebsiella pneumoniae are divergently transcribed sigma 54-dependent promoters that are positively activated by the NifA protein. NifA binds to upstream activator sequences (UASs), usually located 60-200 bp upstream of the start of transcription. Bound NifA is presented to the RNA polymerase-sigma 54 complex (E sigma 54) via DNA loop formation, mediated by the binding of integration host factor protein (IHF) between E sigma 54 and NifA. The nifJ promoter sequence contains three potential NifA binding sites (UAS1, 2 and 3) and two potential RNA polymerase-sigma 54-binding sites (downstream promoter elements, DPEs 1 and 2). DPE2 is located 420 bp into the coding region and DPE1 overlaps UAS1 by 5 bp. Mutational and footprinting analyses have shown efficient activation of the nifJ promoter requires that NifA is bound at UAS 2 and 3. Transcription is initiated at DPE1. Only a weak interaction of NifA with the UAS overlapping DPE1 was detected. Footprints demonstrated that E sigma 54 forms a closed complex at DPE1 but not DPE2 and that bound E sigma 54 closely approaches the -15 region of DPE1. Stimulation of nifJ promoter activity by IHF was not as great as that observed for other nif promoters. In the absence of IHF nifH promoter sequences stimulated activation of the nifJ promoter. This appeared to require NifA bound at the nifH UAS. Thus, one additional role of IHF may be to partition NifA between the two promoters by constraining the topology of the DNA.

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.

Regulation of bacterial gene expression by metal-protein complexes

Metal ions are essential cofactors in several transacting bacterial gene regulators. Upon binding of the metal, the receptor proteins act either as repressors of gene expression or, in other systems, as transcriptional activators. Other metal-dependent regulatory proteins may function, directly or indirectly, as sensors of the cellular oxygen status, and may even be mediators in light-responsive gene regulation.

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 nifH promoter region of Rhizobium leguminosarum: nucleotide sequence and promoter elements controlling activation by NifA protein

The nucleotide (nt) sequence of the Rhizobium leguminosarum nifH promoter region contains a consensus promoter, a consensus upstream activator sequence (UAS), a pseudo (psi) promoter and a psi UAS. We mapped the transcription start point for the consensus promoter sequence by primer extension. This promoter differs from the consensus in one of the four supposedly invariant nt and can be activated by the Klebsiella pneumoniae nifA product in Escherichia coli. Under these conditions the psi promoter and psi UAS do not function. A low-copy-number plasmid construct containing the psi UAS as well as the consensus UAS delayed the onset of symbiotic nitrogen fixation in nodules induced on Pisum sativum. Studies of high-copy-number nifH promoter constructs showed that partial deletion of the consensus UAS does not alter the ability to inhibit nitrogen fixation by titration of NifA suggesting that NifA can also complex with RNA polymerase containing the alternative sigma-factor RpoN.

Molecular linkage of the nif/fix and nod gene regions in Rhizobium leguminosarum biovar trifolii

Nucleotide sequence analysis of a 2.5kb region downstream of the nifA gene from Rhizobium leguminosarum biovar trifolii has resulted in linkage, at the DNA sequence level, of the nifEN, nifHDK, fixABCX, nifA gene cluster with the nodEF, nodD, nodABCIJ genes. Four genes have been identified within this intervening region. Immediately 3' to the nifA gene is the nifB gene and the nifB-linked ferredoxin-encoding fdxN gene. Downstream of fdxN in R. leguminosarum bv. trifolii and in Rhizobium meliloti, we have identified an open reading frame which has not been described previously and which we propose to designate fixU. Downstream of fixU in R. leguminosarum bv. trifolii is a nod gene, nodT, which is contiguous with nodJ (B. Surin et al., manuscript in preparation). As a result of this study, the linkage relationships of 22 symbiotic genes spanning a 24 kb region of the symbiotic plasmid from R. leguminosarum bv. trifolii are now known.

Site-directed mutagenesis of the Klebsiella pneumoniae nitrogenase. Effects of modifying conserved cysteine residues in the alpha- and beta-subunits

The five conserved cysteine residues present in the alpha-subunit and the three conserved cysteine residues present in the beta-subunit of nitrogenase component 1 were individually changed to alanine. Mutations in the alpha-subunit at positions 63, 89, 155 and 275 and in the beta-subunit at positions 69, 94 and 152 all resulted in a loss of diazotrophic growth and component 1 activity and loss of the normal e.p.r. signal of the component 1 protein. Component 2 activity was retained. Replacement of cysteine-184 in the alpha-subunit with alanine greatly diminished, but did not eliminate, diazotrophic growth and component 1 activity. Substitution of serine for cysteine at position 152 in the beta-subunit, in contrast with the substitution of alanine at this position, resulted in the formation of active component 1. Replacement of the non-conserved cysteine-112 in the beta-subunit with alanine did not greatly perturb diazotrophic growth or the activity of component 1. Extracts prepared from a mutant, with cysteine-275 of the alpha-subunit replaced by alanine, complemented extracts of a mutant unable to synthesize the iron-molybdenum cofactor of nitrogenase, indicating that the alanine-275 substitution increases the availability of cofactor. Furthermore extracts of this mutant exhibited an e.p.r. signal similar to that of extracted iron-molybdenum cofactor. These data suggest a role for cysteine-275 as a ligand to the cofactor.

Nucleotide sequence of the regulatory nifA gene of Rhizobium leguminosarum PRE: transcriptional control sites and expression in Escherichia coli

We report the sequence of the regulatory nifA gene of Rhizobium leguminosarum PRE. The transcription initiation and termination sites of nifA were mapped and a potential promoter and a rho-independent terminator identified. The nifA gene has two possible translation start sites, both of which are used in an Escherichia coli background, resulting in proteins with apparent molecular weights of 58 kD and 57 kD; initiation at the second site is preferred over initiation at the first. The nifA-nifB intergenic region contains an rpoN-dependent promoter for the nifB gene but no consensus upstream activator sequence (UAS). A potential DNA-binding domain, consisting of two alpha-helices separated by a four-amino-acid linker, is located at the C-terminal end of the NifA amino acid sequence.

Dual control of the Bradyrhizobium japonicum symbiotic nitrogen fixation regulatory operon fixR nifA: analysis of cis- and trans-acting elements

Aerobic expression of the fixR nifA operon in Bradyrhizobium japonicum was shown to depend on a cis-acting, promoter-upstream DNA sequence located between the -24/-12 promoter and position -86 relative to the transcription start site. An adenine at position -66 was essential for maximal expression. A chromosomal deletion of the upstream activator sequence (UAS) led to a symbiotically defective phenotype which was typical of nifA mutants. B. japonicum crude extracts contained a protein that bound to the UAS. By using chromosomally integrated fixR-lacZ fusions, the level of expression of the fixR nifA operon was found to be fivefold higher under reduced oxygen tension than under aerobiosis. This increase was due to autoactivation by the NifA protein and was partly independent of the UAS. Based on these data, we propose a model for the regulation of nitrogen fixation genes in B. japonicum that involves dual positive control of the fixR nifA operon. At high oxygen concentrations, the operon is expressed at a moderate level, subject to activation by the binding of a trans-acting factor to the UAS. Under such conditions, the nifA gene product is known to be inactive. At very low oxygen concentrations--a condition favorable to NifA activity--the NifA protein is the trans-acting factor which (i) enhances the level of fixR nifA expression (and hence its own synthesis) and (ii) activates other nif and fix genes.

The nifA gene product from Rhizobium leguminosarum biovar trifolii lacks the N-terminal domain found in other NifA proteins

The nifA gene has been identified between the fixX and nifB genes in the clover microsymbiont Rhizobium leguminosarum biovar trifolii (R.I. bv. trifolii) strain ANU843. Expression of the nifA gene is induced in the symbiotic state and site-directed mutagenesis experiments indicate that nifA expression is essential for symbiotic nitrogen fixation. Interestingly, the predicted R.I. bv. trifolii NifA protein lacks an N-terminal domain that is present in the homologous proteins from R.I. bv. viciae, Rhizobium meliloti, Bradyrhizobium japonicum, Klebsiella pneumoniae and all other documented NifA proteins. This indicates that this N-terminal domain is not essential for NifA function in R.I. bv. trifolii.

Construction of chimaeric promoter regions by exchange of the upstream regulatory sequences from fdhF and nif genes

Hybrid 5' regulatory regions were constructed in which the upstream activator sequence (UAS) and promoter of various nif genes were exchanged with the upstream regulatory sequence (URS) of the fdhF gene from Escherichia coli. They were analysed for their regulatory response under different growth conditions with the aid of fdhF'-'lacZ or nif'-'lacZ fusions. Placement of the UAS from the Bradyrhizobium japonicum nifH gene in front of the spacer (DNA region between URS and promoter) plus promoter from fdhF renders fdhF expression activatable by the Klebsiella pneumoniae NIFA protein, both under aerobic and anaerobic conditions. This excludes the possibility that the spacer of the fdhF5' flanking region contains a site recognized by a putative oxygen- or nitrate-responsive repressor. There was also considerable activation by NIFA of fdhF expression in a construct lacking the nifH UAS but containing the fdhF spacer plus promoter. Further experimental evidence suggests that this reflects a direct interaction between NIFA and RNA polymerase at the ntrA-dependent promoter. A second set of hybrid constructs in which the URS from fdhF (E. coli) was placed in front of the nifD spacer plus promoter from B. japonicum or in front of the K. pneumoniae nifH, nifU, nifB spacers and promoters, delivered inactive constructs in the case of the nifD, nifU and nifB genes. However, a nifH'-'lacZ fusion preceded by its own spacer and promoter plus the foreign fdhF URS displayed all the regulatory characteristics of fdhF expression, i.e. anaerobic induction with formate and repression by oxygen and nitrate. Although it is not known why only one out of the four nif promoters could be activated by the fdhF URS, this result nevertheless demonstrates that the various regulatory stimuli affecting expression of fdhF in E. coli have their target at the upstream regulatory sequence.

Mutations in the RNA polymerase recognition sequence of the Klebsiella pneumoniae nifH promoter permitting transcriptional activation in the absence of NifA binding to upstream activator sequences

Positive control of the wild-type Klebsiella pneumoniae nifH promoter by the NifA protein requires that NifA is bound at the upstream activator sequence (UAS). By introducing base substitutions at -15 to -17 in the RNA polymerase recognition sequence of the nifH promoter, positive control by a form of NifA unable to bind to the UAS was greatly increased when compared to the wild-type promoter. Transcriptional activation still required the rpoN encoded sigma factor and was initiated at the same nucleotide as in the wild-type promoter. Mutations at -15 to -17 suppressed the requirement that the UAS should be located on the correct face of the DNA helix with respect to the RNA polymerase recognition sequence in order that titration of NifA and efficient activation occur. This result supports the suggestion that upstream bound NifA interacts with the RNA polymerase-RpoN complex. To examine the minimal carboxy terminal sequences required for the positive control function of NifA a series of carboxy terminal deletions were constructed. Efficient positive control at a UAS-independent promoter was only observed in deletions which did not extend beyond the proposed boundary separating the carboxy terminal NifA DNA-binding domain from its central domain.

Fine-tuning of nif and fix gene expression by upstream activator sequences in Bradyrhizobium japonicum

The significance of Bradyrhizobium japonicum upstream activator sequences (UASs) for differential NifA-mediated fix and nif gene expression was investigated by two means: (i) hybrid fixA- and fixB-lacZ fusions were constructed by transposing a nifH-UAS cartridge in front of their promoters; and (ii) B. japonicum mutants were generated carrying specific chromosomal deletions or UAS cartridge insertions within the fixA, fixB or nifH promoter-upstream regions. Expression of fixA was not affected, and expression of fixB decreased only to 42%, when the respective fixA and fixB promoter-upstream DNAs were deleted. This shows that in B. japonicum the NifA-dependent activation of at least the fixA promoter does not require the presence of a closely adjacent UAS. Deletion of the UASs in front of the nifH gene not only reduced the expression of nifH down to 2.5% but, surprisingly, also resulted in a reduction of the fixB mRNA level to less than 20%. This suggests that the nifH-UASs may exert a long-range effect on the expression of the 3-kb-distant fixBCX operon in nif cluster I or B. japonicum. Artificial transposition of the nifH-UASs in front of the fixA and fixB promoters strongly enhanced fixA and fixB expression.

The DNA-binding domain of the transcriptional activator protein NifA resides in its carboxy terminus, recognises the upstream activator sequences of nif promoters and can be separated from the positive control function of NifA

The positive control protein NifA activates transcription of nitrogen fixation promoters in Klebsiella pneumoniae. NifA is believed to bind to specific sites, the upstream activator sequences (UAS's), of the nif promoters which it activates. We have now shown by mutation of the carboxy terminus of NifA that this is the DNA-binding domain and that the DNA-binding and positive activator functions of NifA can be separated. Mutational analysis of the nifH UAS and in vivo methylation protection analysis of the interaction of NifA with the nifH promoter demonstrates that the UAS is recognised by the carboxy terminus of NifA. The UAS's of K. pneumoniae nif promoters are also required for activation by the Rhizobium meliloti NifA indicating that this activator also possesses DNA-binding activity.

NifA-dependent in vivo protection demonstrates that the upstream activator sequence of nif promoters is a protein binding site

Primer-extension analysis of the Klebsiella pneumoniae nifH promoter was used to determine changes in the accessibility of the promoter DNA to methylation after exposure of growing cells to dimethyl sulfate. Four guanine residues present in the nifH upstream activator sequence (UAS), the proposed NifA binding site, were protected from methylation and two guanine residues were hypermethylated when the transcriptional activator protein NifA was present in the cells. The interaction detected at the nifH UAS was independent of the alternative sigma factor NtrA required for transcription of the nifH and other nif promoters. Mutations within the nifH UAS that diminish NifA-dependent transcriptional activation reduced the interaction at the UAS. It seems likely that the pattern of methylation protection observed in the nifH UAS is the result of NifA binding.

The role of activator binding sites in transcriptional control of the divergently transcribed nifF and nifLA promoters from Klebsiella pneumoniae

The regulatory region spanning the divergently transcribed nifF and nifLA promoters contains a NIFA-specific upstream activator sequence (UAS) located around +59, and two NTRC binding sites centred at -142 and -163 with respect to the nifLA transcription start site. We have constructed mutations in each of these binding sites and examined their role in transcriptional activation of the divergently transcribed promoters. Analysis of a mutation at +60 confirms that the UAS is required for efficient NIFA-mediated activation of nifF transcription. This sequence is also required for maximal activation of the nifLA promoter. Mutations at -169 and -148, within the two NTRC binding sites, reduce activation of the nifLA promoter by NTRC in vivo and lower the affinity of the activator for these sites in vitro. Phosphorylation of NTRC by NTRB is required for efficient binding of NTRC to these sites.