Rhizobium meliloti regulatory gene fixJ activates transcription of R. meliloti nifA and fixK genes in Escherichia coli

Role of the Solute-Binding Protein CuaD in the Signaling and Regulating Pathway of Cellobiose and Cellulose Utilization in Ruminiclostridium cellulolyticum

In Ruminiclostridium cellulolyticum, cellobiose is imported by the CuaABC ATP-binding cassette transporter containing the solute-binding protein (SBP) CuaA and is further degraded in the cytosol by the cellobiose phosphorylase CbpA. The genes encoding these proteins have been shown to be essential for cellobiose and cellulose utilization. Here, we show that a second SBP (CuaD), whose gene is adjacent to two genes encoding a putative two-component regulation system (CuaSR), forms a three-component system with CuaS and CuaR. Studies of mutant and recombinant strains of R. cellulolyticum have indicated that cuaD is important for the growth of strains on cellobiose and cellulose. Furthermore, the results of our RT-qPCR experiments suggest that both the three (CuaDSR)- and the two (CuaSR)-component systems are able to perceive the cellobiose signal. However, the strain producing the three-component system is more efficient in its cellobiose and cellulose utilization. As CuaD binds to CuaS, we propose an in-silico model of the complex made up of two extracellular domains of CuaS and two of CuaD. CuaD allows microorganisms to detect very low concentrations of cellobiose due to its high affinity and specificity for this disaccharide, and together with CuaSR, it triggers the expression of the cuaABC-cbpA genes involved in cellodextrins uptake.

Multiple sensors provide spatiotemporal oxygen regulation of gene expression in a Rhizobium-legume symbiosis

Regulation by oxygen (O₂) in rhizobia is essential for their symbioses with plants and involves multiple O₂ sensing proteins. Three sensors exist in the pea microsymbiont Rhizobium leguminosarum Rlv3841: hFixL, FnrN and NifA. At low O₂ concentrations (1%) hFixL signals via FxkR to induce expression of the FixK transcription factor, which activates transcription of downstream genes. These include fixNOQP, encoding the high-affinity cbb₃-type terminal oxidase used in symbiosis. In free-living Rlv3841, the hFixL-FxkR-FixK pathway was active at 1% O₂, and confocal microscopy showed hFixL-FxkR-FixK activity in the earliest stages of Rlv3841 differentiation in nodules (zones I and II). Work on Rlv3841 inside and outside nodules showed that the hFixL-FxkR-FixK pathway also induces transcription of fnrN at 1% O₂ and in the earliest stages of Rlv3841 differentiation in nodules. We confirmed past findings suggesting a role for FnrN in fixNOQP expression. However, unlike hFixL-FxkR-FixK, Rlv3841 FnrN was only active in the near-anaerobic zones III and IV of pea nodules. Quantification of fixNOQP expression in nodules showed this was driven primarily by FnrN, with minimal direct hFixL-FxkR-FixK induction. Thus, FnrN is key for full symbiotic expression of fixNOQP. Without FnrN, nitrogen fixation was reduced by 85% in Rlv3841, while eliminating hFixL only reduced fixation by 25%. The hFixL-FxkR-FixK pathway effectively primes the O₂ response by increasing fnrN expression in early differentiation (zones I-II). In zone III of mature nodules, near-anaerobic conditions activate FnrN, which induces fixNOQP transcription to the level required for wild-type nitrogen fixation activity. Modelling and transcriptional analysis indicates that the different O₂ sensitivities of hFixL and FnrN lead to a nuanced spatiotemporal pattern of gene regulation in different nodule zones in response to changing O₂ concentration. Multi-sensor O₂ regulation is prevalent in rhizobia, suggesting the fine-tuned control this enables is common and maximizes the effectiveness of the symbioses.

Rhizobia are soil bacteria that form a symbiosis with legume plants. In exchange for shelter from the plant, rhizobia provide nitrogen fertilizer, produced by nitrogen fixation. Fixation is catalysed by the nitrogenase enzyme, which is inactivated by oxygen. To prevent this, plants house rhizobia in root nodules, which create a low oxygen environment. However, rhizobia need oxygen, and must adapt to survive the low oxygen concentration in the nodule. Key to this is regulating their genes based on oxygen concentration. We studied one Rhizobium species which uses three different protein sensors of oxygen, each turning on at a different oxygen concentration. As the bacteria get deeper inside the plant nodule and the oxygen concentration drops, each sensor switches on in turn. Our results also show that the first sensor to turn on, hFixL, primes the second sensor, FnrN. This prepares the rhizobia for the core region of the nodule where oxygen concentration is lowest and most nitrogen fixation takes place. If both sensors are removed, the bacteria cannot fix nitrogen. Many rhizobia have several oxygen sensing proteins, so using multiple sensors is likely a common strategy enabling rhizobia to adapt to low oxygen precisely and in stages during symbiosis.

Oxygen regulatory mechanisms of nitrogen fixation in rhizobia

Rhizobia are α- and β-proteobacteria that form a symbiotic partnership with legumes, fixing atmospheric dinitrogen to ammonia and providing it to the plant. Oxygen regulation is key in this symbiosis. Fixation is performed by an oxygen-intolerant nitrogenase enzyme but requires respiration to meet its high energy demands. To satisfy these opposing constraints the symbiotic partners cooperate intimately, employing a variety of mechanisms to regulate and respond to oxygen concentration. During symbiosis rhizobia undergo significant changes in gene expression to differentiate into nitrogen-fixing bacteroids. Legumes host these bacteroids in specialized root organs called nodules. These generate a near-anoxic environment using an oxygen diffusion barrier, oxygen-binding leghemoglobin and control of mitochondria localization. Rhizobia sense oxygen using multiple interconnected systems which enable a finely-tuned response to the wide range of oxygen concentrations they experience when transitioning from soil to nodules. The oxygen-sensing FixL-FixJ and hybrid FixL-FxkR two-component systems activate at relatively high oxygen concentration and regulate fixK transcription. FixK activates the fixNOQP and fixGHIS operons producing a high-affinity terminal oxidase required for bacterial respiration in the microaerobic nodule. Additionally or alternatively, some rhizobia regulate expression of these operons by FnrN, an FNR-like oxygen-sensing protein. The final stage of symbiotic establishment is activated by the NifA protein, regulated by oxygen at both the transcriptional and protein level. A cross-species comparison of these systems highlights differences in their roles and interconnections but reveals common regulatory patterns and themes. Future work is needed to establish the complete regulon of these systems and identify other regulatory signals.

Mycobacterium tuberculosis DevR/DosR Dormancy Regulator Activation Mechanism: Dispensability of Phosphorylation, Cooperativity and Essentiality of α10 Helix

DevR/DosR is a well-characterized regulator in Mycobacterium tuberculosis which is implicated in various processes ranging from dormancy/persistence to drug tolerance. DevR induces the expression of an ~48-gene dormancy regulon in response to gaseous stresses, including hypoxia. Strains of the Beijing lineage constitutively express this regulon, which may confer upon them a significant advantage, since they would be ‘pre-adapted’ to the environmental stresses that predominate during infection. Aerobic DevR regulon expression in laboratory-manipulated overexpression strains is also reported. In both instances, the need for an inducing signal is bypassed. While a phosphorylation-mediated conformational change in DevR was proposed as the activation mechanism under hypoxia, the mechanism underlying constitutive expression is not understood. Because DevR is implicated in bacterial dormancy/persistence and is a promising drug target, it is relevant to resolve the mechanistic puzzle of hypoxic activation on one hand and constitutive expression under ‘non-inducing’ conditions on the other. Here, an overexpression strategy was employed to elucidate the DevR activation mechanism. Using a panel of kinase and transcription factor mutants, we establish that DevR, upon overexpression, circumvents DevS/DosT sensor kinase-mediated or small molecule phosphodonor-dependent activation, and also cooperativity-mediated effects, which are key aspects of hypoxic activation mechanism. However, overexpression failed to rescue the defect of C-terminal-truncated DevR lacking the α10 helix, establishing the α10 helix as an indispensable component of DevR activation mechanism. We propose that aerobic overexpression of DevR likely increases the concentration of α10 helix-mediated active dimer species to above the threshold level, as during hypoxia, and enables regulon expression. This advance in the understanding of DevR activation mechanism clarifies a long standing question as to the mechanism of DevR overexpression-mediated induction of the regulon in the absence of the normal environmental cue and establishes the α10 helix as an universal and pivotal targeting interface for DevR inhibitor development.

A two-component system (XydS/R) controls the expression of genes encoding CBM6-containing proteins in response to straw in Clostridium cellulolyticum

The composition of the cellulosomes (multi enzymatic complexes involved in the degradation of plant cell wall polysaccharides) produced by Clostridium cellulolyticum differs according to the growth substrate. In particular, the expression of a cluster of 14 hemicellulase-encoding genes (called xyl-doc) seems to be induced by the presence of straw and not of cellulose. Genes encoding a putative two-component regulation system (XydS/R) were found upstream of xyl-doc. First evidence for the involvement of the response regulator, XydR, part of this two-component system, in the expression of xyl-doc genes was given by the analysis of the cellulosomes produced by a regulator overproducing strain when grown on cellulose. Nano-LC MS/MS analysis allowed the detection of the products of all xyl-doc genes and of the product of the gene at locus Ccel_1656 predicted to bear a carbohydrate binding domain targeting hemicellulose. RT-PCR experiments further demonstrated that the regulation occurs at the transcriptional level and that all xyl-doc genes are transcriptionally linked. mRNA quantification in a regulator knock-out strain and in its complemented derivative confirmed the involvement of the regulator in the expression of xyl-doc genes and of the gene at locus Ccel_1656 in response to straw. Electrophoretic mobility shift assays using the purified regulator further demonstrated that the regulator binds to DNA regions located upstream of the first gene of the xyl-doc gene cluster and upstream of the gene at locus Ccel_1656.

Sinorhizobium meliloti nifA mutant induces different gene expression profile from wild type in Alfalfa nodules

Several studies have demonstrated that the Rhizobium nifA gene is an activator of nitrogen fixation acting in nodule bacteria. To understand the effects of the Sinorhizobium meliloti nifA gene on Alfalfa, the cDNA-AFLP technique was employed to study the changes in gene expression in nifA mutant nodules. Among the approximately 3,000 transcript-derived fragments, 37 had differential expression levels. These expression levels were subsequently confirmed by reverse Northern blot and RT-polymerase chain reaction. Sequence analyses revealed that 21 cDNA fragments corresponded to genes involved in signal communication, protein degradation, nutrient metabolism, cell growth and development.

Detection of and response to signals involved in host-microbe interactions by plant-associated bacteria

Diverse interactions between hosts and microbes are initiated by the detection of host-released chemical signals. Detection of these signals leads to altered patterns of gene expression that culminate in specific and adaptive changes in bacterial physiology that are required for these associations. This concept was first demonstrated for the members of the family Rhizobiaceae and was later found to apply to many other plant-associated bacteria as well as to microbes that colonize human and animal hosts. The family Rhizobiaceae includes various genera of rhizobia as well as species of Agrobacterium. Rhizobia are symbionts of legumes, which fix nitrogen within root nodules, while Agrobacterium tumefaciens is a pathogen that causes crown gall tumors on a wide variety of plants. The plant-released signals that are recognized by these bacteria are low-molecular-weight, diffusible molecules and are detected by the bacteria through specific receptor proteins. Similar phenomena are observed with other plant pathogens, including Pseudomonas syringae, Ralstonia solanacearum, and Erwinia spp., although here the signals and signal receptors are not as well defined. In some cases, nutritional conditions such as iron limitation or the lack of nitrogen sources seem to provide a significant cue. While much has been learned about the process of host detection over the past 20 years, our knowledge is far from being complete. The complex nature of the plant-microbe interactions makes it extremely challenging to gain a comprehensive picture of host detection in natural environments, and thus many signals and signal recognition systems remain to be described.

Regulatory role of Rhizobium etli CNPAF512 fnrN during symbiosis

The Rhizobium etli CNPAF512 fnrN gene was identified in the fixABCX rpoN(2) region. The corresponding protein contains the hallmark residues characteristic of proteins belonging to the class IB group of Fnr-related proteins. The expression of R. etli fnrN is highly induced under free-living microaerobic conditions and during symbiosis. This microaerobic and symbiotic induction of fnrN is not controlled by the sigma factor RpoN and the symbiotic regulator nifA or fixLJ, but it is due to positive autoregulation. Inoculation of Phaseolus vulgaris with an R. etli fnrN mutant strain resulted in a severe reduction in the bacteroid nitrogen fixation capacity compared to the wild-type capacity, confirming the importance of FnrN during symbiosis. The expression of the R. etli fixN, fixG, and arcA genes is strictly controlled by fnrN under free-living microaerobic conditions and in bacteroids during symbiosis with the host. However, there is an additional level of regulation of fixN and fixG under symbiotic conditions. A phylogenetic analysis of the available rhizobial FnrN and FixK proteins grouped the proteins in three different clusters.

A novel autoregulation mechanism of fnrN expression in Rhizobium leguminosarum bv viciae

The fnrN gene from Rhizobium leguminosarum UPM791 controls microaerobic expression of both nitrogen fixation and hydrogenase activities in symbiotic cells. Two copies of fnrN are present in this strain, one chromosomal (fnrN1) and the other located in the symbiotic plasmid (fnrN2). Their expression was studied by cloning the regulatory regions in lacZ promoter-probe vectors. The fnrN genes were found to be autoregulated: they are expressed only at basal levels under aerobic conditions; they are highly expressed under microaerobic conditions; and they are expressed at basal levels in the double mutant DG2 (fnrN1 fnrN2) under any condition. The promoters of both genes contain two FnrN-binding sequences (anaeroboxes), centred at positions -12.5 (proximal anaerobox) and -44.5 (distal anaerobox). Expression analysis and gel retardation experiments with fnrN1-derivative promoter mutants altered in key bases of the anaerobox sequences demonstrated that binding of FnrN1 to the distal anaerobox is necessary for microaerobic activation of transcription, and that binding of FnrN1 to the proximal anaerobox results in transcriptional repression. The apparent affinity of FnrN1 for the proximal anaerobox was fivefold lower than for the distal anaerobox, resulting in repression of transcription of fnrN1 only at high-FnrN1 concentrations. This positive and negative autoregulation mechanism ensures an equilibrated expression of fnrN in response to microaerobic conditions.

The two-component regulators GacS and GacA influence accumulation of the stationary-phase sigma factor sigmaS and the stress response in Pseudomonas fluorescens Pf-5

Three global regulators are known to control antibiotic production by Pseudomonas fluorescens. A two-component regulatory system comprised of the sensor kinase GacS (previously called ApdA or LemA) and GacA, a member of the FixJ family of response regulators, is required for antibiotic production. A mutation in rpoS, which encodes the stationary-phase sigma factor sigmaS, differentially affects antibiotic production and reduces the capacity of stationary-phase cells of P. fluorescens to survive exposure to oxidative stress. The gacA gene of P. fluorescens Pf-5 was isolated, and the influence of gacS and gacA on rpoS transcription, sigmaS levels, and oxidative stress response of Pf-5 was determined. We selected a gacA mutant of Pf-5 that contained a single nucleotide substitution within a predicted alpha-helical region, which is highly conserved among the FixJ family of response regulators. At the entrance to stationary phase, sigmaS content in gacS and gacA mutants of Pf-5 was less than 20% of the wild-type level. Transcription of rpoS, assessed with an rpoS-lacZ transcriptional fusion, was positively influenced by GacS and GacA, an effect that was most evident at the transition between exponential growth and stationary phase. Mutations in gacS and gacA compromised the capacity of stationary-phase cells of Pf-5 to survive exposure to oxidative stress. The results of this study provide evidence for the predominant roles of GacS and GacA in the regulatory cascade controlling stress response and antifungal metabolite production in P. fluorescens.

Transcriptional regulation of Alcaligenes eutrophus hydrogenase genes

Alcaligenes eutrophus H16 produces a soluble hydrogenase (SH) and a membrane-bound hydrogenase (MBH) which catalyze the oxidation of H2, supplying the organism with energy for autotrophic growth. The promoters of the structural genes for the SH and the MBH, PSH and PMBH, respectively, were identified by means of the primer extension technique. Both promoters were active in vivo under hydrogenase-derepressing conditions but directed only low levels of transcription under condition which repressed hydrogenase synthesis. The cellular pools of SH and MBH transcripts under the different growth conditions correlated with the activities of the respective promoters. Also, an immediate and drastic increase in transcript pool levels occurred upon derepression of the hydrogenase system. Both promoters were dependent on the minor sigma factor sigma 54 and on the hydrogenase regulator HoxA in vivo. PSH was stronger than PMBH under both heterotrophic and autotrophic growth conditions. The two promoters were induced at approximately the same rates upon derepression of the hydrogenase system in diauxic cultures. The response regulator HoxA mediated low-level activation of PSH and PMBH in a heterologous system.

New classes of mutants in complementary chromatic adaptation provide evidence for a novel four-step phosphorelay system

Complementary chromatic adaptation appears to be controlled by a complex regulatory system with similarity to four-step phosphorelays. Such pathways utilize two histidine and two aspartate residues for signal transduction. Previous studies of the signaling system controlling complementary chromatic adaptation have uncovered two elements of this pathway, a putative sensor, RcaE, and a response regulator, RcaC. In this work, we describe a second response regulator controlling complementary chromatic adaptation, RcaF, and identify putative DNA binding and histidine phosphoacceptor domains within RcaC. RcaF is a small response regulator with similarity to SpoOF of Bacillus subtilis; the latter functions in the four-step phosphorelay system controlling sporulation. We have also determined that within this phosphorelay pathway, RcaE precedes RcaF, and RcaC is probably downstream of RcaE and RcaF. This signal transduction pathway is novel because it appears to use at least five, instead of four, phosphoacceptor domains in the phosphorelay circuit.

Dual function of PilS during transcriptional activation of the Pseudomonas aeruginosa pilin subunit gene

The polar pili of Pseudomonas aeruginosa are composed of subunits encoded by the pilA gene. Expression of pilA requires the alternative sigma factor RpoN and a pair of regulatory elements, PilS and PilR. These two proteins are members of the two-component regulatory family, in which PilS is the sensory component and PilR is the response regulator. By using expression and localization analyses, in this work we show that PilS is synthesized as a 59-kDa polypeptide located in the P. aeruginosa cytoplasmic membrane. When the pilS gene is expressed in Escherichia coli, aberrant translational initiation results in a smaller, 40-kDa polypeptide. Unexpectedly, overexpression of pilS in P. aeruginosa results in decreased transcription of the pilA gene. Moreover, fully functional PilS was not required for this inhibitory effect. A mutation in the histidine residue essential for kinase activity resulted in a protein unable to activate transcription, yet when overexpressed in the presence of the wild-type PilS protein, this protein still repressed pilin synthesis. A shorter form of PilS, lacking its transmembrane segments, was active and fully capable of stimulating pilA transcription but when overexpressed did not show the inhibitory effect on pilin expression seen with full-length PilS. We also show that overexpression of pilR can activate transcription of pilA even in the absence of PilS. On the basis of our studies, we propose a complex mechanism of regulation of PilS function, involving other cellular factors that control PilS and its activities during the phosphorelay mechanism of signal transduction.

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.

Oxygen regulation of expression of nitrogen fixation genes in Rhizobium meliloti

The sensor kinase FixL and the response regulator FixJ induce the expression of the nitrogen fixation genes of Rhizobium meliloti in response to microaerobiosis, which is a characteristic feature of the plant root nodule interior where the bacteria fix nitrogen. The kinase activity of a purified, soluble derivative of the membrane-bound hemoprotein FixL, designated FixL*, is stimulated under low oxygen conditions, thus increasing FixJ-phosphate levels. FixJ-phosphate is a potent transcriptional activator of the nifA and fixK genes, the products of which, in turn, induce the expression of most if not all of the remaining nitrogen fixation genes. FixL* and FixL*-phosphate also dephosphorylate FixJ-phosphate, and this activity is depressed by low oxygen concentrations. In the current model, gene expression is reciprocally coordinated by the kinase and phosphatase activities of FixL according to changes in oxygen tension.

FixL of Rhizobium meliloti enhances the transcriptional activity of a mutant FixJD54N protein by phosphorylation of an alternate residue

In Rhizobium meliloti, transcription of nitrogen fixation genes is induced in oxygen-depleted conditions under the control of the two-component regulatory system FixLJ. FixJ is a transcriptional activator whose activity is dramatically enhanced by phosphorylation, whereas FixL is a hemoprotein kinase that controls the level of phosphorylated FixJ in response to oxygen availability. We have found that a mutant FixJ protein, FixJD54N, in which the presumed site of phosphorylation (aspartate 54) was changed to an asparagine, is strongly affected for phosphorylation by FixL and is not detectably phosphorylated from the low-molecular-weight phosphate donor, acetyl-phosphate. Unexpectedly, FixL strongly enhances the transcriptional activity of the FixJD54N protein both in vivo and in vitro. We present evidence that FixJD54N transcriptional activity is enhanced by phosphorylation of an alternate residue in a reaction that requires FixL and ATP and is not affected by oxygen. We also demonstrate the key role of Asp-54 of FixJ in oxygen signal transduction.

Oxygen control in Rhizobium

Rhizobia are gram-negative bacteria with two distinct habitats: the soil rhizosphere in which they have a saprophytic and, usually, aerobic life and a plant ecological niche, the legume nodule, which constitutes a microoxic environment compatible with the operation of the nitrogen reducing enzyme nitrogenase. The purpose of this review is to summarize the present knowledge of the changes induced in these bacteria when shifting to a microoxic environment. Oxygen concentration regulates the expression of two major metabolic pathways: energy conservation by respiratory chains and nitrogen fixation. After reviewing the genetic data on these metabolic pathways and their response to oxygen we will put special emphasis on the regulatory molecules which are involved in the control of gene expression. We will show that, although homologous regulatory molecules allow response to oxygen in different species, they are assembled in various combinations resulting in a variable regulatory coupling between genes for microaerobic respiration and nitrogen fixation genes. The significance of coordinated regulation of genes not essential for nitrogen fixation with nitrogen fixation genes will also be discussed.

Mutants of the two-component regulatory protein FixJ of Rhizobium meliloti that have increased activity at the nifA promoter

FixL and FixJ belong to a two-component regulatory system in Rhizobium meliloti that induces the expression of numerous nitrogen-fixation genes during symbiosis with alfalfa. FixJ is a positive activator required for transcription of the regulatory genes nifA and fixK, while FixL is an oxygen-binding hemoprotein capable of regulating the phosphorylation status of both itself and FixJ, in response to oxygen availability. In this study, we isolated four FixJ mutants that display increased activity at the nifA promoter (PnifA) in Escherichia coli. All four mutants possess amino acid changes in a domain of FixJ that is conserved in other response regulator proteins, and all exhibit increased activity at PnifA in R. meliloti that is dependent on the presence of FixL. One of the mutant proteins, while less efficient at accepting phosphate from a truncated derivative of FixL (FixL*), nevertheless has a phosphorylated form that is more stable than the phosphorylated form of wild-type (wt) FixJ and is more resistant to the phosphatase activity of FixL*. The wt FixJ-phosphate was found to have a half-life of approximately 4 h, which makes it an unusually long-lived response regulator protein. The exceptional stability of wt FixJ-phosphate and the altered phosphorylation properties observed for the mutant are discussed in relation to signal transduction in the FixLJ system.

Oxygen-regulated in vitro transcription of Rhizobium meliloti nifA and fixK genes

Oxygen concentration regulates the expression of nitrogen fixation genes in the symbiotic bacterium Rhizobium meliloti. We demonstrate that two proteins, FixL and FixJ, that belong to the two-component family of regulatory proteins are necessary and sufficient for oxygen-regulated in vitro transcription of the two key regulatory genes, nifA and fixK. We show directly that FixJ is a transcriptional activator, working in conjunction with the RNA polymerase sigma 70 holoenzyme. Addition of FixL122, a soluble form of the sensor FixL protein, to the transcription assay enhanced FixJ transcriptional activity in response to low oxygen concentration. This enhancement of FixJ activity was correlated with FixJ phosphorylation.

Use of a promoter-probe vector system in the cloning of a new NifA-dependent promoter (ndp) from Bradyrhizobium japonicum

Many of the symbiotic nitrogen-fixation genes in the soybean root nodule bacterium, Bradyrhizobium japonicum, are transcribed from -24/-12 promoters that are recognized by the sigma 54-RNA polymerase and activated by the transcriptional regulator protein, NifA. Several lines of evidence suggest that the B. japonicum genome has more than those seven NifA-regulated promoters which were characterized previously. Here, we present a strategy aimed at the cloning of new NifA-activated promoters. It makes use of (i) a promoter-probe vector into which random B. japonicum genomic fragments were cloned in front of a promoterless reporter gene and (ii) a screening procedure that allowed us to distinguish constitutive promoters from promoters that were specifically activated by NifA under microaerobic or anaerobic conditions. With certain modifications, the system may be generally applicable to clone positively regulated, anaerobically induced genes. A novel NifA-dependent promoter region (ndp) of B. japonicum was found by these means. The transcription start point was mapped, and its 5'-flanking DNA carried a -24/-12-type promoter sequence plus potential binding sites for NifA and integration host factor. Further transcript analyses confirmed that maximal transcription from this promoter occurred only in the presence of NifA and sigma 54 during anaerobic growth of B. japonicum. In Escherichia coli, expression of beta-galactosidase derived from a transcriptional ndp::lacZ fusion was activated 11-fold by B. japonicum NifA, and this activation also required sigma 54 but was independent of NtrC. The DNA around ndp shared no similarity with known sequences in databases.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxygen regulation of nifA transcription in vitro

In Rhizobium meliloti, transcription of the key nitrogen-fixation regulatory genes nifA and fixK is induced in response to microaerobiosis through the action of the FixL and FixJ proteins. These two proteins are sensor and regulator homologues, respectively, of a large family of bacterial two-component systems involved in sensing and responding to environmental changes. A soluble, truncated form of the membrane protein FixL, FixL*, has been shown to be a hemoprotein that phosphorylates and dephosphorylates FixJ in response to oxygen tension. Here we use an in vitro transcription system to prove that FixJ is a transcriptional activator of both nifA and fixK and that phosphorylation of FixJ markedly increases its activity. Phosphorylation was achieved either by preincubating FixJ with FixL* and ATP or by exposing FixJ to the inorganic phospho donor ammonium hydrogen phosphoramidate. Both FixJ and FixJ-phosphate formed heparin-resistant complexes under the assay conditions used. Lastly, we were able to show that anaerobiosis, in the presence of FixL* and ATP, greatly stimulates FixJ activity at the nifA promoter with either Escherichia coli or R. meliloti RNA polymerase. This use of atmospheric oxygen to control nifA transcription in vitro represents a reconstitution of a bacterial two-component signal transduction system in its entirety, from effector to ultimate target, by the use of purified components.

Modular structure of the FixL protein of Rhizobium meliloti

FixL protein of Rhizobium meliloti is a haemo-protein kinase which activates the transcription of nifA and fixK genes via the transcriptional activator protein FixJ under microaerobic conditions. FixL and FixJ proteins belong to the family of two-component regulatory systems for which primary sequence data predicts a modular structure. We showed, using Escherichia coli as heterologous host, that FixL indeed has a modular structure. The amino-terminal hydrophobic domain is dispensable for the oxygen-regulated activity of FixL in vivo. The central cytoplasmic non-conserved domain is necessary for the oxygen-sensing function of FixL whereas it is not necessary for the activation of FixJ by FixL. We propose that, under aerobic conditions, the central domain represses the activating function associated with the carboxy-terminal conserved domain.

Ammonia regulation of the Rhizobium meliloti nitrogenase structural and regulatory genes under free-living conditions: involvement of the fixL gene product?

The expression under microaerobic conditions of the Rhizobium meliloti nifA and consequently the nifHDK genes was found to be negatively regulated by ammonia and nitrate. Assimilation of the ammonia to glutamate and glutamine is not required for this regulation to occur. This indicates that ammonia itself, and not a product of its metabolism, may be regulating nif expression. Unlike the situation in Klebsiella pneumoniae, NtrC is apparently not involved in mediating the ammonia effect on nifA expression in R. meliloti. Neither does the fixK gene product, which is known to regulate nifA in R. meliloti, appear to be involved in mediating the ammonia effect. The regulation of nifA by ammonia is shown to be mediated through the FixL protein. A truncated fixJ gene, the product of which has been shown to induce nifA expression irrespective of the oxygen status of the cell, also circumvented the repressive effect of ammonia on nifA expression. This suggests that the ammonia effect is mediated through the FixLJ regulatory cascade. Interestingly no effect of ammonia on fixK expression was observed.

Isolation of phosphorylation-deficient mutants of the Rhizobium meliloti two-component regulatory protein, FixJ

Rhizobium meliloti FixL and FixJ are members of a symbiotically essential two-component system that regulates nitrogen-fixation genes in response to environmental oxygen concentrations. FixL is a membrane protein that is thought to relay information about oxygen availability to FixJ via a phosphotransfer mechanism. FixJ increases expression of the nifA and fixK genes by activating transcription of the nifA and fixK promoters (p-nifA and p-fixK, respectively). In this study, we examined the relationship between the in vivo activity of FixJ as a transcriptional regulator and its ability to be phosphorylated in vitro by the sensor FixL. FixJ mutants were isolated that showed decreased activity on p-nifA in Escherichia coli. Most of the FixJ mutant proteins also showed decreased activity on the fixK promoter. These mutants were analysed in R. meliloti for activity on p-nifA during vegetative growth, where similarities and differences were observed when compared with their phenotypes in E. coli. Three mutants showing significantly less activity in R. meliloti were examined for symbiotic activity in planta and were found to be ineffective. When these three mutant FixJ proteins were examined in vitro for their ability to be phosphorylated by FixL, two mutants were found to have a significantly decreased ability to accept phosphate from FixL. These findings are discussed in relation to signal transduction in the FixLJ system.

Molecular genetic analysis of the Rhizobium meliloti fixK promoter: identification of sequences involved in positive and negative regulation

Transcription of the Rhizobium meliloti fixK gene is induced in symbiotic and microaerobic growth conditions by the FixL/FixJ modulator/effector pair. Transcription of fixK is also negatively autoregulated. By 5' deletion analysis, the involvement in negative regulation of a DNA region between -514 and -450 with respect to the transcription start was demonstrated. Site-directed mutagenesis allowed us to show that a sequence homologous to the binding site of the Escherichia coli Fnr protein, centred at position -487, participates in this effect. However, deletion or mutagenesis of this Fnr-like sequence does not completely eliminate FixK-dependent repression, which suggests that either an additional DNA region is involved in negative regulation or that it is mediated at the level of fixLJ transcription. Deletion analysis also allowed the definition of a DNA region involved in FixJ-mediated activation of the fixK promoter, between -79 and -42. Different point mutations in the -60, -45 and -35 regions were shown to affect promoter activity. In some cases, the activity of mutant promoters could be partly or fully restored by increasing the expression of the fixLJ regulatory genes, in an E. coli strain harbouring a plasmid with fixLJ under the control of an inducible (p-tac) promoter.

Mutational analysis of the Rhizobium meliloti nifA promoter

The nifA gene of Rhizobium meliloti, the bacterial endosymbiont of alfalfa, is a regulatory nitrogen fixation gene required for the induction of several key nif and fix genes. Transcription of nifA is strongly induced in planta and under microaerobic conditions ex planta. Induction of nifA, in turn, is positively controlled by the fixL and fixJ genes of R. meliloti, the sensor and regulator, respectively, of a two-component system responsible for oxygen sensing by this bacterium. This system is also responsible for the positive induction of fixK. Here, we report that chemical and oligonucleotide site-directed mutageneses of the nifA promoter (nifAp) were conducted to identify nucleotides essential for induction. Nineteen mutants, including 14 single-point mutants, were analyzed for microaerobic induction of nifAp in R. meliloti. Critical residues were identified in an upstream region between base pairs -54 and -39 relative to the transcription start site. Attempts at separating the upstream and downstream regions of the nifA promoter so as to maintain fixJ-dependent activity were unsuccessful. A 5' deletion of the fixK promoter (fixKp) to -67 indicates that sequences upstream of this position are not required for microaerobic induction. A sequence comparison of the -54 to -39 region of nifAp with the upstream sequences of fixKp does not reveal a block of identical nucleotides that could account for the fixJ-dependent microaerobic induction of both promoters. Many of the defective nifAp mutants in this region, however, are in residues with identity to fixKp in an alignment of the promoters according to their transcription start sites. Therefore, it is possible that there is a common sequence motif in the -54 to -39 region of the two promoters that is required for fixLJ-dependent microaerobic induction.

Characterization of a novel Azorhizobium caulinodans ORS571 two-component regulatory system, NtrY/NtrX, involved in nitrogen fixation and metabolism

Azorhizobium caulinodans ORS571 nifA regulation is partially mediated by the nitrogen regulatory gene ntrC. However, the residual nifA expression in ntrC mutant strains is still modulated by the cellular nitrogen and oxygen status. A second ntrC-homologous region, linked to ntrC, was identified and characterized by site-directed insertion mutagenesis and DNA sequencing. Tn5 insertions in this region cause pleiotropic defects in nitrogen metabolism and affect free-living as well as symbiotic nitrogen fixation. DNA sequencing and complementation studies revealed the existence of a bicistronic operon (ntrYX). NtrY is likely to represent the transmembrane 'sensor' protein element in a two-component regulatory system. NtrX shares a high degree of homology with NtrC proteins of other organisms and probably constitutes the regulator protein element. The regulation of the ntrYX and ntrC loci and the effects of ntrYX, ntrY and ntrX mutations on nifA expression were examined using beta-galactosidase gene fusions. NtrY/NtrX were found to modulate nifA expression and ntrYX transcription was shown to be partially under the control of NtrC.

In vitro activity of the nitrogen fixation regulatory protein FIXJ from Rhizobium meliloti

Cell extracts of an Escherichia coli strain that overproduces the regulatory protein FIXJ from Rhizobium meliloti promoted transcription of fixK, a known FIXJ-dependent gene, in a coupled transcription-translation assay. Activation by FIXJ was dependent on the sigma 70 holoenzyme form of RNA polymerase.

Influence of oxygen on DNA binding, positive control, and stability of the Bradyrhizobium japonicum NifA regulatory protein

Central to the genetic regulatory circuit that controls Bradyrhizobium japonicum nif and fix gene expression is the NifA protein. NifA activates transcription of several nif and fix genes and autoregulates its expression during symbiosis in soybean root nodules or in free-living microaerobic conditions. High O2 tensions result in the lack of nif expression, possibly by inactivation of NifA through oxidation of an essential metal cofactor. Several B. japonicum nif and fix promoters have upstream activator sequences (UAS) required for optimal activation. The UAS are located more than 100 bp from the -24/-12 promoter and have been proposed to be binding sites for NifA. We investigated the interaction of NifA with the nifD promoter region by using in vivo dimethyl sulfate footprinting. NifA-dependent protection from methylation of the two UAS of this promoter was detected. Footprinting experiments in the presence of rifampin showed that UAS-bound NifA led to the formation of an open nifD promoter-RNA polymerase sigma 54 complex. Shift to aerobic growth resulted in a rapid loss of protection of both the UAS and the promoter, indicating that the DNA-binding and the activation functions of NifA were controlled by the O2 status of the cell. After an almost complete inactivation by oxygen, the NifA protein began to degrade. Furthermore, metal deprivation also caused degradation of NifA. In this case, however, the rates of NifA inactivation and NifA degradation were not clearly distinguishable. The results are discussed in the light of a previously proposed model, according to which the oxidation state of a NifA-metal complex influences the conformation of NifA for both DNA-binding and positive control functions.

Modular structure of FixJ: homology of the transcriptional activator domain with the -35 binding domain of sigma factors

The FixL/FixJ two-component system is a global regulator of nitrogen-fixation genes in Rhizobium meliloti. The transcriptional activator FixJ contains two modules: its N-terminal module is homologous with other two-component regulators; its C-terminal module shows homology with various transcriptional activators, and with the C-terminal region of sigma factors, which is involved in the discrimination of the -35 region of bacterial promoters. We show that the C-terminal module of FixJ contains the entire transcription activation function, and that the N-terminal module regulates this activity negatively. Oligonucleotide-directed mutagenesis of the transcriptional activator module demonstrated the importance of a potential helix-turn-helix structure.

The regulatory status of the fixL- and fixJ-like genes in Bradyrhizobium japonicum may be different from that in Rhizobium meliloti

The cloning, sequencing and mutational analysis of the Bradyrhizobium japonicum symbiotic nitrogen fixation genes fixL and fixJ are reported here. The two genes were adjacent and probably formed an operon, fixLJ. The predicted FixL and FixJ proteins, members of the two-component sensor/regulator family, were homologous over almost their entire lengths to the corresponding Rhizobium meliloti proteins (approx. 50% identity). Downstream of the B. japonicum fixJ gene was found an open reading frame with 138 codons (ORF138) whose product shared 36% homology with the N-terminal part of FixJ. Deletion and insertion mutations within fixL and fixJ led to a loss of approximately 90% wild-type symbiotic nitrogen fixation (Fix) activity, whereas an ORF138 mutant was Fix+. In fixL, fixJ and ORF138 mutant backgrounds, the aerobic expression of the fixR-nifA operon was not affected. NifA itself did not regulate the expression of the fixJ gene. Thus, the B. japonicum FixL and FixJ proteins were neither involved in the regulation of aerobic nifA gene expression nor in the anaerobic NifA-dependent autoregulation of the fixRnifA operon, rather they appeared to control symbiotically important genes other than those whose expression was dependent on the NifA protein. The fixL and fixJ mutant strains were unable to grow anaerobically with nitrate as the terminal electron acceptor. Therefore, some of the FixJ-dependent genes in B. japonicum may be concerned with anaerobic respiration.

An Fnr-like protein encoded in Rhizobium leguminosarum biovar viciae shows structural and functional homology to Rhizobium meliloti FixK

A 1.9 kb DNA region of Rhizobium leguminosarum biovar viciae strain VF39 capable of promoting microaerobic and symbiotic induction of the Rhizobium meliloti fixN gene was identified by heterologous complementation. Sequence analysis of this DNA region revealed the presence of two complete open reading frames, orf240 and orf114. The deduced amino acid sequence of orf240 showed significant homology to Escherichia coli Fnr and R. meliloti FixK. The major difference between ORF240 and FixK is the presence of 21 N-terminal amino acids in ORF240 that have no counterpart in FixK. A similar protein domain is also present in E. coli Fnr and is essential for the oxygen-regulated activity of this protein. Analysis of the nucleotide sequence upstream of orf240 revealed a motif similar to the NtrA-dependent promoter consensus sequence, as well as two DNA regions resembling the Fnr consensus binding sequence. A Tn5-generated mutant in orf240 lost the ability to induce the R. meliloti fixN-lacZ fusion. Interestingly, this mutant was still capable of nitrogen fixation but showed reduced nitrogenase activity.

Rhizobium meliloti Fix L is an oxygen sensor and regulates R. meliloti nifA and fixK genes differently in Escherichia coli

In Rhizobium meliloti, nif and fix genes, involved in nitrogen fixation during symbiosis with alfalfa, are under the control of two transcriptional regulators encoded by nifA and fixK. Expression of nifA and fixK is under the control of FixL/J, a two-component regulatory system. We showed, using Escherichia coli as a heterologous host, that FixL/J controls nifA and fixK expression in response to microaerobiosis. Furthermore, expression of the sensor gene fixL and of the activator gene fixJ under the control of two different promoters allowed us to show that FixL mediates microaerobic induction of nifA when the level of FixJ is low and aerobic repression of nifA when the level of FixJ is high. Similarly, activation of fixK occurred in microaerobiosis when the FixJ level was low in the presence of FixL. In contrast to nifA, fixK expression was not affected by FixL in aerated cultures when the level of FixJ was high. We conclude that R. meliloti FixL senses oxygen in the heterologous host E. coli consistent with the microaerobic induction of nifA and fixK in R. meliloti and that nifA and fixK promoters are differentially activated by FixJ in response to the oxygen signal.

Temporal and spatial regulation of the symbiotic genes of Rhizobium meliloti in planta revealed by transposon Tn5-gusA

Tn5-gusA promoter/probe transposons have been constructed that fuse the Escherichia coli gusA reporter gene transcriptionally or translationally with a target promoter. These have been used to monitor expression of Rhizobium meliloti symbiotic genes within alfalfa nodules. Fusions in all 11 nod genes studied show the same pattern of expression: first on the root surface, then throughout the developing nodule, then mainly in the nodule meristem, falling off progressively through the central region, and then disappearing. In contrast, fusions in all five nif genes studied, all four fix genes, and syrM show a second, different pattern: expression beginning later, first throughout the nodule except for the meristem, strongest just behind the meristem, and falling off progressively through the central region. Novel features revealed by these studies include nod expression in the meristem, regulated in planta expression of control genes nodD1 and nodD3, disappearance of nod expression late in organogenesis, and properties of syrM.

Inactivation, sequence, and lacZ fusion analysis of a regulatory locus required for repression of nitrogen fixation genes in Rhodobacter capsulatus

Transcription of the genes that code for proteins involved in nitrogen fixation in free-living diazotrophs is typically repressed by high internal oxygen concentrations or exogenous fixed nitrogen. The DNA sequence of a regulatory locus required for repression of Rhodobacter capsulatus nitrogen fixation genes was determined. It was shown that this locus, defined by Tn5 insertions and by ethyl methanesulfonate-derived mutations, is homologous to the glnB gene of other organisms. The R. capsulatus glnB gene was upstream of glnA, the gene for glutamine synthetase, in a glnBA operon. beta-Galactosidase expression from an R. capsulatus glnBA-lacZ translational fusion was increased twofold in cells induced by nitrogen limitation relative to that in cells under nitrogen-sufficient conditions. R. capsulatus nifR1, a gene that was previously shown to be homologous to ntrC and that is required for transcription of nitrogen fixation genes, was responsible for approximately 50% of the transcriptional activation of this glnBA fusion in cells induced under nitrogen-limiting conditions. R. capsulatus GLNB, NIFR1, and NIFR2 (a protein homologous to NTRB) were proposed to transduce the nitrogen status in the cell into repression or activation of other R. capsulatus nif genes. Repression of nif genes in response to oxygen was still present in R. capsulatus glnB mutants and must have occurred at a different level of control in the regulatory circuit.