Identification of a functional fur gene in Bradyrhizobium japonicum

Convergent gene pair dSH3 and irr regulate Pi and Fe homeostasis in Bradyrhizobium diazoefficiens USDA110 and symbiotic nitrogen fixation efficiency

The nitrogen-fixing bacteroids inhabit inside legume root nodules must manage finely the utilization of P and Fe, the two most critical elements, due to their antagonistic interactions. While the balance mechanism for them remains unclear. A double SH3 domain-containing protein (dSH3) in the Bradyrhizobium diazoefficiens USDA110 was found to inhibit the alkaline phosphatase activity, thereby reducing P supply from organophosphates. The dSH3 gene is adjacent to the irr gene, which encodes the iron response repressor and regulates Fe homeostasis under Fe-limited conditions. Their transcription directions converge to a common intergenic sequence (IGS) region, forming a convergent transcription. Extending the IGS region through Tn5 transposon or pVO155 plasmid insertion significantly down-regulated expression of this gene pair, leading to a remarkable accumulation of P and an inability to grow under Fe-limited conditions. Inoculation of soybean with either of the insertion mutants resulted in N2-fixing failure. However, the IGS-deleted mutant showed no visible changes in N2-fixing efficiency on soybean compared to that inoculated with wild type. These findings reveal a novel regulative strategy in the IGS region and its flanking convergent gene pair for antagonistic utilization of P and Fe in rhizobia and coordination of N2-fixing efficiency.

Transcriptomic Response of the Diazotrophic Bacteria Gluconacetobacter diazotrophicus Strain PAL5 to Iron Limitation and Characterization of the fur Regulatory Network

Gluconacetobacter diazotrophicus has been the focus of several studies aiming to understand the mechanisms behind this endophytic diazotrophic bacterium. The present study is the first global analysis of the early transcriptional response of exponentially growing G. diazotrophicus to iron, an essential cofactor for many enzymes involved in various metabolic pathways. RNA-seq, targeted gene mutagenesis and computational motif discovery tools were used to define the G. diazotrophicusfur regulon. The data analysis showed that genes encoding functions related to iron homeostasis were significantly upregulated in response to iron limitations. Certain genes involved in secondary metabolism were overexpressed under iron-limited conditions. In contrast, it was observed that the expression of genes involved in Fe-S cluster biosynthesis, flagellar biosynthesis and type IV secretion systems were downregulated in an iron-depleted culture medium. Our results support a model that controls transcription in G. diazotrophicus by fur function. The G. diazotrophicusfur protein was able to complement an E. colifur mutant. These results provide new insights into the effects of iron on the metabolism of G. diazotrophicus, as well as demonstrate the essentiality of this micronutrient for the main characteristics of plant growth promotion by G. diazotrophicus.

Metal-specific control of gene expression mediated by Bradyrhizobium japonicum Mur and Escherichia coli Fur is determined by the cellular context

Bradyrhizobium japonicum Mur and Escherichia coli Fur are manganese- and iron-responsive transcriptional regulators, respectively, that belong to the same protein family. Here, we show that neither Mur nor Fur discriminate between Fe(2+) and Mn(2+) in vitro nor is there a metal preference for conferral of DNA-binding activity on the purified proteins. When expressed in E. coli, B. japonicum Mur responded to iron, but not manganese, as determined by in vivo promoter occupancy and transcriptional repression activity. Moreover, E. coli Fur activity was manganese-dependent in B. japonicum. Total and chelatable iron levels were higher in E. coli than in B. japonicum under identical growth conditions, and Mur responded to iron in a B. japonicum iron export mutant that accumulated high levels of the metal. However, elevated manganese content in E. coli did not confer activity on Fur or Mur, suggesting a regulatory pool of manganese in B. japonicum that is absent in E. coli. We conclude that the metal selectivity of Mur and Fur depends on the cellular context in which they function, not on intrinsic properties of the proteins. Also, the novel iron sensing mechanism found in the rhizobia may be an evolutionary adaptation to the cellular manganese status.

Perception and Homeostatic Control of Iron in the Rhizobia and Related Bacteria

Iron is an essential nutrient, but it can also be toxic. Therefore, iron homeostasis must be strictly regulated. Transcriptional control of iron-dependent gene expression in the rhizobia and other taxa of the Alphaproteobacteria is fundamentally different from the Fur paradigm in Escherichia coli and other model systems. Rather than sense iron directly, the rhizobia employ the iron response regulator (Irr) to monitor and respond to the status of an iron-dependent process, namely, heme biosynthesis. This novel control mechanism allows iron homeostasis to be integrated with other cellular processes, and it permits differential control of iron regulon genes in a manner not readily achieved by Fur. Moreover, studies of Irr have defined a role for heme in conditional protein stability that has been subsequently described in eukaryotes. Finally, Irr-mediated control of iron metabolism may reflect a cellular strategy that accommodates a greater reliance on manganese.

Engineering rhizobial bioinoculants: a strategy to improve iron nutrition

Under field conditions, inoculated rhizobial strains are at a survival disadvantage as compared to indigenous strains. In order to out-compete native rhizobia it is not only important to develop strong nodulation efficiency but also increase their competence in the soil and rhizosphere. Competitive survival of the inoculated strain may be improved by employing strain selection and by genetic engineering of superior nitrogen fixing strains. Iron sufficiency is an important factor determining the survival and nodulation by rhizobia in soil. Siderophores, a class of ferric specific ligands that are involved in receptor specific iron transport into bacteria, constitute an important part of iron acquisition systems in rhizobia and have been shown to play a role in symbiosis as well as in saprophytic survival. Soils predominantly have iron bound to hydroxamate siderophores, a pool that is largely unavailable to catecholate-utilizing rhizobia. Outer membrane receptors for uptake of ferric hydroxamates include FhuA and FegA which are specific for ferrichrome siderophore. Increase in nodule occupancy and enhanced plant growth of the fegA and fhuA expressing engineered bioinoculants rhizobial strain have been reported. Engineering rhizobia for developing effective bioinoculants with improved ability to utilize heterologous siderophores could provide them with better iron acquisition ability and consequently, rhizospheric stability.

Bacterial outer membrane channel for divalent metal ion acquisition

The prevailing model of bacterial membrane function predicts that the outer membrane is permeable to most small solutes because of pores with limited selectivity based primarily on size. Here, we identified mnoP in the Gram-negative bacterium Bradyrhizobium japonicum as a gene coregulated with the inner membrane Mn(2+) transporter gene mntH. MnoP is an outer membrane protein expressed specifically under manganese limitation. MnoP acts as a channel to facilitate the tranlocation of Mn(2+), but not Co(2+) or Cu(2+), into reconstituted proteoliposomes. An mnoP mutant is defective in high-affinity Mn(2+) transport into cells and has a severe growth phenotype under manganese limitation. We suggest that the outer membrane is a barrier to divalent metal ions that requires a selective channel to meet the nutritional needs of the cell.

Transcriptional control of the Bradyrhizobium japonicum irr gene requires repression by fur and Antirepression by Irr

Bradyrhizobium japonicum Fur mediates manganese-responsive transcriptional control of the mntH gene independently of iron, but it also has been implicated in iron-dependent regulation of the irr gene. Thus, we sought to address the apparent discrepancy in Fur responsiveness to metals. Irr is a transcriptional regulator found in iron-limited cells. Here, we show that irr gene mRNA was regulated by both iron and manganese, and repression occurred only in the presence of both metals. Under these conditions, Fur occupied the irr promoter in vivo in the parent strain, and irr mRNA expression was derepressed in a fur mutant. Under low iron conditions, the irr promoter was occupied by Irr, but not by Fur, and control by manganese was lost. Fur occupancy of the irr promoter was dependent on manganese, but not iron, in an irr mutant, suggesting that Irr normally interferes with Fur binding. Correspondingly, regulation of irr mRNA was dependent only on manganese in the irr strain. The Irr binding site within the irr promoter partially overlaps the Fur binding site. DNase I footprinting analysis showed that Irr interfered with Fur binding in vitro. In addition, Fur repression of transcription from the irr promoter in vitro was relieved by Irr. We conclude that Fur mediates manganese-dependent repression of irr transcription and that Irr acts as an antirepressor under iron limitation by preventing Fur binding to the promoter.

The mntH gene encodes the major Mn(2+) transporter in Bradyrhizobium japonicum and is regulated by manganese via the Fur protein

The bacterial Nramp family protein MntH is a divalent metal transporter, but mntH mutants have little or no phenotype in organisms where it has been studied. Here, we identify the mntH homologue of Bradyrhizobium japonicum, and demonstrate that it is essential for Mn(2+) transport and for maintenance of cellular manganese homeostasis. Transport activity was induced under manganese deficiency, and Fe(2+) did not compete with (54)Mn(2+) for uptake by cells. The steady-state level of mntH mRNA was negatively regulated by manganese, but was unaffected by iron. Control of mntH expression and Mn(2+) transport by manganese was lost in a fur strain, resulting in constitutively high activity. Fur protected a 35 bp region of the mntH promoter in DNase I footprinting analysis that includes three imperfect direct repeat hexamers that are needed for full occupancy. Mn(2+) increased the affinity of Fur for the mntH promoter by over 50-fold, with a K(d) value of 2.2 nM in the presence of metal. The findings identify MntH as the major Mn(2+) transporter in B. japonicum, and show that Fur is a manganese-responsive regulator in that organism. Furthermore, Fe(2+) is neither a substrate for MntH nor a regulator of mntH expression in vivo.

Positive control of ferric siderophore receptor gene expression by the Irr protein in Bradyrhizobium japonicum

Ferric siderophore receptors are components of high-affinity iron-chelate transport systems in gram-negative bacteria. The genes encoding these receptors are generally regulated by repression. Here, we show that the ferrichrome receptor gene bll4920 and four additional putative ferric siderophore receptor genes in Bradyrhizobium japonicum are positively controlled by the regulatory protein Irr, as observed by the low level of mRNA transcripts in an irr mutant in iron-limited cells. Potential Irr binding sites with iron control element (ICE)-like motifs were found upstream and distal to the transcription start sites of the five receptor genes. However, purified recombinant Irr bound only some of those elements. Nevertheless, dissection of the bll4920 promoter region showed that a component in extracts of wild-type cells grown in iron-limited media bound only in the ICE motif region of the promoter. This binding was not observed with extracts of cells from the parent strain grown under high-iron conditions or from an irr mutant strain. Furthermore, gel mobility supershift experiments identified Irr as the binding protein in cell extracts. Chromatin immunoprecipitation experiments demonstrated that Irr occupies the promoters of the five ferric iron transport genes in vivo. We conclude that Irr is a direct positive regulator of ferric iron transport in B. japonicum.

Sinorhizobium meliloti fur-like (Mur) protein binds a fur box-like sequence present in the mntA promoter in a manganese-responsive manner

In Sinorhizobium meliloti, the Mur(Sm) protein, a homologue of the ferric uptake regulator (Fur), mediates manganese-dependent regulation of the MntABCD manganese uptake system. In this study, we analyzed Mur(Sm) binding to the promoter region of the S. meliloti mntA gene. We demonstrated that Mur(Sm) protein binds with high affinity to the promoter region of mntA gene in a manganese-responsive manner. Moreover, the results presented here indicate that two monomers, or one dimer, of Mur(Sm) binds the DNA. The binding region was identified by DNase I footprinting analysis and covers a region of about 30 bp long that contains a palindromic sequence. The Mur(Sm) binding site, present in the mntA promoter region, is similar to a Fur box; however, manganese-activated Mur(Sm) binds a canonical Fur box with very low affinity. Furthermore, the data obtained indicate that Mur(Sm) responds to physiological concentrations of manganese.

Molecular characterization of the Fur protein of Listeria monocytogenes

Iron is essential for the survival of almost all organisms, although excess iron can result in the generation of free radicals which are toxic to cells. To avoid the toxic effects of free radicals, the concentration of intracellular iron is generally regulated by the ferric uptake regulator Fur in bacteria. The 150 aa fur ORF from Listeria monocytogenes was cloned into pRSETa, and the His-tagged fusion protein was purified by nickel affinity column chromatography. DNA binding activity of this protein was studied by an electrophoretic mobility shift assay using the end-labelled promoters P(fhuDC) and P(fur). The results showed a decrease in migration for both promoter DNAs in the presence of the Fur protein, and the change in migration was competitively inhibited with an excess of the same unlabelled promoters. No shift in migration was observed when a similar assay was performed using non-specific end-labelled DNA. The assay showed that binding of Fur to P(fur) or P(fhuDC) was independent of iron or manganese ions, and was not inhibited in the presence of 2 mM EDTA. Inductively coupled plasma MS of the Fur protein showed no iron or manganese, but 0.48 mole zinc per mole protein was detected. A DNase I protection assay revealed that Fur specifically bound to and protected a 19 bp consensus Fur box sequence located in the promoters of fur and fhuDC. There was no requirement for iron or manganese in this assay also. However, Northern blot analysis showed an increase in fur transcription under iron-restricted compared to high-level conditions. Thus, the study suggests that under in vitro conditions, the affinity of the Fur protein for the 19 bp Fur box sequence does not require iron, but iron availability regulates fur transcription in vivo. Thus, the regulation by Fur in this intracellular pathogen may be dependent on either the structure of the DNA binding domain or other intracellular factors yet to be identified.

Living without Fur: the subtlety and complexity of iron-responsive gene regulation in the symbiotic bacterium Rhizobium and other α-proteobacteria

The alpha-proteobacteria include several important genera, including the symbiotic N(2)-fixing "rhizobia", the plant pathogen Agrobacterium, the mammalian pathogens Brucella, Bartonella as well as many others that are of environmental or other interest--including Rhodobacter, Caulobacter and the hugely abundant marine genus Pelagibacter. Only a few species--mainly different members of the rhizobia--have been analyzed directly for their ability to use and to respond to iron. These studies, however, have shown that at least some of the "alphas" differ fundamentally in the ways in which they regulate their genes in response to Fe availability. In this paper, we build on our own work on Rhizobium leguminosarum (the symbiont of peas, beans and clovers) and on Bradyrhizobium japonicum, which nodulates soybeans and which has been studied in Buffalo and Zürich. In the former species, the predominant Fe-responsive regulator is not Fur, but RirA, a member of the Rrf2 protein family and which likely has an FeS cluster cofactor. In addition, there are several R. leguminosarum genes that are expressed at higher levels in Fe-replete conditions and at least some of these are regulated by Irr, a member of the Fur superfamily and which has the unusual property of being degraded by the presence of heme. In silico analyses of the genome sequences of other bacteria indicate that Irr occurs in all members of the Rhizobiales and the Rhodobacterales and that RirA is found in all but one branch of these two lineages, the exception being the clade that includes B. japonicum. Nearly all the Rhizobiales and the Rhodobacterales contain a gene whose product resembles bona fide Fur. However, direct genetic studies show that in most of the Rhizobiales and in the Rhodobacterales it is a "Mur" (a manganese responsive repressor of a small number of genes involved in Mn uptake) or, in Bradyrhizobium, it recognizes the operator sequences of only a few genes that are involved in Fe metabolism. We propose that the Rhizobiales and the Rhodobacterales have relegated Fur to a far more minor role than in (say) E. coli and that they employ Irr and, in the Rhizobiales, RirA as their global Fe-responsive transcriptional regulators. In contrast to the direct interaction between Fe2+ and conventional Fur, we suggest that these bacteria sense Fe more indirectly as functions of the intracellular concentrations of FeS clusters and of heme. Thus, their "iron-omes" may be more accurately linked to the real-time needs for the metal and not just to its absolute concentration in the environment.

Functional specialization within the Fur family of metalloregulators

The ferric uptake regulator (Fur) protein, as originally described in Escherichia coli, is an iron-sensing repressor that controls the expression of genes for siderophore biosynthesis and iron transport. Although Fur is commonly thought of as a metal-dependent repressor, Fur also activates the expression of many genes by either indirect or direct mechanisms. In the best studied model systems, Fur functions as a global regulator of iron homeostasis controlling both the induction of iron uptake functions (under iron limitation) and the expression of iron storage proteins and iron-utilizing enzymes (under iron sufficiency). We now appreciate that there is a tremendous diversity in metal selectivity and biological function within the Fur family which includes sensors of iron (Fur), zinc (Zur), manganese (Mur), and nickel (Nur). Despite numerous studies, the mechanism of metal ion sensing by Fur family proteins is still controversial. Other family members use metal catalyzed oxidation reactions to sense peroxide-stress (PerR) or the availability of heme (Irr).

Computational reconstruction of iron- and manganese-responsive transcriptional networks in alpha-proteobacteria

We used comparative genomics to investigate the distribution of conserved DNA-binding motifs in the regulatory regions of genes involved in iron and manganese homeostasis in alpha-proteobacteria. Combined with other computational approaches, this allowed us to reconstruct the metal regulatory network in more than three dozen species with available genome sequences. We identified several classes of cis-acting regulatory DNA motifs (Irr-boxes or ICEs, RirA-boxes, Iron-Rhodo-boxes, Fur-alpha-boxes, Mur-box or MRS, MntR-box, and IscR-boxes) in regulatory regions of various genes involved in iron and manganese uptake, Fe-S and heme biosynthesis, iron storage, and usage. Despite the different nature of the iron regulons in selected lineages of alpha-proteobacteria, the overall regulatory network is consistent with, and confirmed by, many experimental observations. This study expands the range of genes involved in iron homeostasis and demonstrates considerable interconnection between iron-responsive regulatory systems. The detailed comparative and phylogenetic analyses of the regulatory systems allowed us to propose a theory about the possible evolution of Fe and Mn regulons in alpha-proteobacteria. The main evolutionary event likely occurred in the common ancestor of the Rhizobiales and Rhodobacterales, where the Fur protein switched to regulating manganese transporters (and hence Fur had become Mur). In these lineages, the role of global iron homeostasis was taken by RirA and Irr, two transcriptional regulators that act by sensing the physiological consequence of the metal availability rather than its concentration per se, and thus provide for more flexible regulation.

The availability of hundreds of complete genomes allows one to use comparative genomics to describe key metabolic processes and regulatory gene networks. Genome context analyses and comparisons of transcription factor binding sites between genomes offer a powerful approach for functional gene annotation. Reconstruction of transcriptional regulatory networks allows for better understanding of cellular processes, which can be substantiated by direct experimentation. Iron homeostasis in bacteria is conferred by the regulation of various iron uptake transporters, iron storage ferritins, and iron-containing enzymes. In high concentrations, iron is poisonous for the cell, so strict control of iron homeostasis is maintained, mostly at the level of transcription by iron-responsive regulators. Despite their general importance, iron regulatory networks in most bacterial species are not well-understood. In this study, Rodionov and colleagues applied comparative genomic approaches to describe the regulatory network formed by genes involved in iron homeostasis in the alpha subclass of proteobacteria, which have extremely versatile lifestyles. These networks are mediated by a set of various DNA motifs (or regulatory signals) that occur in 5′ gene regions and involve at least six different metal-responsive regulators. This study once again shows the power of comparative genomics in the analysis of complex regulatory networks and their evolution.

The Bradyrhizobium japonicum Fur protein is an iron-responsive regulator in vivo

The Fur protein is a global regulator of iron metabolism in many bacterial species. However, Fur homologs from some rhizobia appear not to mediate iron-dependent gene expression in vivo. Here, transcriptional profiling analysis showed that more than one-fourth of the genes within the iron stimulon of Bradyrhizobium japonicum were aberrantly controlled by iron in a fur mutant. However, Fur has only a modest role in regulating iron transport genes. Quantitative real time reverse transcriptase PCR measurements confirmed abnormal gene expression in iron-limited cells of the fur strain, thereby demonstrating that Fur must function under those conditions. The findings show that B. japonicum Fur is involved in iron-dependent gene expression, and support the conclusion that rhizobial Fur proteins have novel functions compared with well studied model systems.

Beyond the Fur paradigm: iron-controlled gene expression in rhizobia

Iron is critical for bacterial growth, but problems arise from the toxicity of excess iron; thus, iron uptake is subject to tight control. The most widely found and best-studied iron-responsive regulator in Gram-negative bacteria is the ferric uptake regulator Fur. In recent years, however, it has become apparent that iron regulation in rhizobia differs from that in many other bacteria. New regulators (RirA, Irr, Mur) were identified which appear to mediate functions that in other bacteria are accomplished by Fur. Even though some of them belong to the Fur family, they exhibit properties that clearly separate them from genuine Fur proteins. This article surveys the principal mechanisms of iron acquisition and uptake in rhizobia, and puts particular emphasis on recent findings on transcriptional regulators and their means to sense the cellular iron status and to regulate gene expression. In this context, we point out differences and similarities with regard to the operators, regulons and structure of the discussed iron regulatory proteins.

Bradyrhizobium japonicum senses iron through the status of haem to regulate iron homeostasis and metabolism

The Irr protein from the bacterium Bradyrhizobium japonicum is expressed under iron limitation to mediate iron control of haem biosynthesis. The regulatory input to Irr is the status of haem and its precursors iron and protoporphyrin at the site of haem synthesis. Here, we show that Irr controls the expression of iron transport genes and many other iron-regulated genes not directly involved in haem synthesis. Irr is both a positive and negative effector of gene expression, and in at least some cases the control is direct. Loss of normal iron responsiveness of those genes in an irr mutant, as well as a lower total cellular iron content, suggests that Irr is required for the correct perception of the cellular iron status. Degradation of Irr in iron replete cells requires haem. Accordingly, control of Irr-regulated genes by iron was aberrant in a haem-defective strain, and iron replete mutant cells behave as if they are iron-limited. In addition, the haem mutant had an abnormally high cellular iron content. The findings indicate that B. japonicum senses iron via the status of haem biosynthesis in an Irr-dependent manner to regulate iron homeostasis and metabolism.

The Iron control element, acting in positive and negative control of iron-regulated Bradyrhizobium japonicum genes, is a target for the Irr protein

Bradyrhizobium japonicum, the nitrogen-fixing soybean symbiont, possesses a heme uptake system encoded by the gene cluster hmuVUT-hmuR-exbBD-tonB. Transcription of the divergently oriented hmuT and hmuR genes was previously found to be induced by iron limitation and to depend on a 21-bp promoter-upstream iron control element (ICE). Here, we show by deletion analysis that the full-length ICE is needed for this type of positive control. Additional genes associated with ICE-like motifs were identified in the B. japonicum genome, of which bll6680 and blr7895 code for bacterioferritin and rubrerythrin homologs, respectively. Transcription start site mapping revealed that their ICEs directly overlap with either the -10 promoter region or the transcription initiation site, suggesting an involvement of the ICE in negative control of both genes. Consistent with this inference was the observed down-regulation of both genes under iron limitation, which in the case of bll6680 was shown to require an intact ICE motif. Using a yeast one-hybrid system, we demonstrated in vivo interaction of the iron response regulator (Irr) with all three ICEs. Moreover, specific in vitro binding of purified Irr protein to the ICE motifs of bll6680 and blr7895 was shown in electrophoretic mobility shift experiments. A genome-wide survey for iron-regulated genes with a custom-made Affymetrix gene chip revealed 17 genes to be induced and 68 to be repressed under iron-replete conditions. Remarkably, ICE-like motifs are associated with a large subset of those B. japonicum genes. We propose the ICE as an important cis-acting element in B. japonicum which represents the DNA-binding site for the Irr protein and, depending on its location within promoter regions, is involved in positive or negative control of the associated iron-regulated genes.

Iron-dependent cytochrome c1 expression is mediated by the status of heme in Bradyrhizobium japonicum

The heme prosthetic group of heme proteins contains iron, which can be a limiting nutrient. Here, we show that cytochrome c1 protein from Bradyrhizobium japonicum was strongly affected by the iron status, with low expression in cells grown under iron limitation. This control was not affected in mutants encoding the iron regulator Irr or Fur. Furthermore, cytochrome c1 mRNA was not influenced by the iron status, suggesting control at a posttranscriptional step. Cytochrome c1 protein levels were very low in mutants defective in the genes encoding delta-aminolevulinic acid (ALA) synthase and ferrochelatase, enzymes that catalyze the first and final steps of the heme biosynthetic pathway, respectively. Iron-dependent cytochrome c1 expression was restored in the ALA synthase mutant by supplementation of the medium with the heme precursor ALA. Supplementation with heme resulted in high levels of cytochrome c1 protein in the wild type and in both mutants, but expression was no longer iron dependent. Cytochrome c1 is synthesized as a protein precursor fused with cytochrome b. A plasmid-borne construct encoding only cytochrome c1 was expressed in an iron- and heme-dependent manner similar to that of the wild-type gene, indicating that control by those effectors is not linked to posttranslational processing of the fusion protein. Mutation of the cytochrome c1 cysteines involved in covalent binding to heme nearly abolished immunodetectable protein. Thus, defects in heme synthesis or heme binding abrogate cytochrome c1 accumulation, apparently due to protein degradation. We suggest that iron-dependent cytochrome c1 expression is mediated by heme availability for heme protein formation.

Fur is involved in manganese-dependent regulation of mntA (sitA) expression in Sinorhizobium meliloti

Fur is a transcriptional regulator involved in iron-dependent control of gene expression in many bacteria. In this work we analyzed the phenotype of a fur mutant in Sinorhizobium meliloti, an alpha-proteobacterium that fixes N(2) in association with host plants. We demonstrated that some functions involved in high-affinity iron transport, siderophore production, and iron-regulated outer membrane protein expression respond to iron in a Fur-independent manner. However, manganese-dependent expression of the MntABCD manganese transport system was lost in a fur strain as discerned by constitutive expression of a mntA::gfp fusion reporter gene in the mutant. Thus, Fur directly or indirectly regulates a manganese-dependent function. The data indicate a novel function for a bacterial Fur protein in mediating manganese-dependent regulation of gene expression.

The Fur-like protein Mur of Rhizobium leguminosarum is a Mn(2+)-responsive transcriptional regulator

In wild-type Rhizobium leguminosarum, the sitABCD operon specifies a Mn(2+) transporter whose expression is severely reduced in cells grown in the presence of this metal. Mutations in the R. leguminosarum gene, mur (manganese uptake regulator), whose product resembles the Fur transcriptional regulator, cause high-level expression of sitABCD in the presence of Mn(2+). In gel-shift mobility assays, purified R. leguminosarum Mur protein bound to at least two regions near the sitABCD promoter region, although this DNA has no conventional consensus Fur-binding sequences (fur boxes). Thus, in contrast to gamma-proteobacteria, where Fur binds Fe(2+), the R. leguminosarum Fur homologue, Mur, act as a Mn(2)-responsive transcriptional regulator.

The ferric uptake regulator (Fur) protein from Bradyrhizobium japonicum is an iron-responsive transcriptional repressor in vitro

The Fur protein represses transcription of iron-responsive genes in bacteria. The discovery that Fur is a zinc metalloprotein and the use of surrogate metals for Fe(2+) for in vitro studies question whether Fur is a direct iron sensor. In the present study, we show that the affinity of Fur from Bradyrhizobium japonicum (BjFur) for its target DNA increases 30-fold in the presence of metal, with a K(d) value of about 2 nM. DNase I footprinting experiments showed that BjFur protected its binding site within the irr gene promoter in the presence of Fe(2+) but not in the absence of metal, showing that DNA binding is Fe(2+)-dependent. BjFur did not inhibit in vitro transcription from the irr promoter using purified components in the absence of metal, but BjFur repressed transcription in the presence of Fe(2+). Thus, BjFur is an iron-responsive transcriptional repressor in vitro. A regulatory Fe(2+)-binding site (site 1) and a structural Zn(2+)-binding site (site 2) inferred from the recent crystal structure of Fur from Pseudomonas aeruginosa are composed of amino acids highly conserved in many Fur proteins, including BjFur. BjFur mutants containing substitutions in site 1 (BjFurS1) or site 2 (BjFurS2) bound DNA with high affinity and repressed transcription in vitro in an Fe(2+)-dependent manner. Interestingly, only a single dimer of BjFurS2 occupied the irr promoter, whereas the wild type and BjFurS1 displayed one- or two-dimer occupancy. We suggest that the putative functions for metal-binding sites deduced from the structure of P. aeruginosa Fur cannot be extrapolated to bacterial Fur proteins as a whole.

A dominant-negative fur mutation in Bradyrhizobium japonicum

In many bacteria, the ferric uptake regulator (Fur) protein plays a central role in the regulation of iron uptake genes. Because iron figures prominently in the agriculturally important symbiosis between soybean and its nitrogen-fixing endosymbiont Bradyrhizobium japonicum, we wanted to assess the role of Fur in the interaction. We identified a fur mutant by selecting for manganese resistance. Manganese interacts with the Fur protein and represses iron uptake genes. In the presence of high levels of manganese, bacteria with a wild-type copy of the fur gene repress iron uptake systems and starve for iron, whereas fur mutants fail to repress iron uptake systems and survive. The B. japonicum fur mutant, as expected, fails to repress iron-regulated outer membrane proteins in the presence of iron. Unexpectedly, a wild-type copy of the fur gene cannot complement the fur mutant. Expression of the fur mutant allele in wild-type cells leads to a fur phenotype. Unlike a B. japonicum fur-null mutant, the strain carrying the dominant-negative fur mutation is unable to form functional, nitrogen-fixing nodules on soybean, mung bean, or cowpea, suggesting a role for a Fur-regulated protein or proteins in the symbiosis.

A novel DNA-binding site for the ferric uptake regulator (Fur) protein from Bradyrhizobium japonicum

The Fur protein is a global regulator of iron metabolism and other processes in many bacterial species. A key feature of the model of Fur function is the recognition of a DNA element within target promoters with similarity to a 19-bp AT-rich palindromic sequence called a Fur box. The irr gene from Bradyrhizobium japonicum is under the control of Fur. Here, we provide evidence that B. japonicum Fur (BjFur) binds to the irr gene promoter with high affinity despite the absence of DNA sequence similarity to the Fur box consensus. Both Escherichia coli Fur and BjFur bound a synthetic Fur box consensus DNA element in electrophoretic gel mobility shift assays, but only BjFur bound the irr promoter. BjFur maximally protected a 30-bp region in DNase I footprinting analysis that includes three imperfect direct repeat hexamers. BjFur formed a high mobility complex and a low mobility complex with DNA in electrophoretic gel mobility shift assays corresponding to occupancy by a single dimer and two dimers or a tetramer, respectively. A mutation in the downstream direct repeat DNA sequence allowed high mobility complex formation only. In vitro transcription from the wild type irr promoter or from a mutated promoter that allowed only dimer occupancy was repressed by Fur, indicating that the dimer can be a functional repressor unit. Our findings identify a novel DNA-binding element for Fur and suggest that the Fur box consensus may not completely represent the target sequences for bacterial Fur proteins as a whole. In addition, Fur binding to a target promoter is sufficient to repress transcription in vitro.

fur-independent regulation of the Pasteurella multocida hbpA gene encoding a haemin-binding protein

Treatment of bacterial cultures with chelating agents such as 2,2'-dipyridyl (DPD) induces expression of iron-regulated genes. It is known that in the gamma-Proteobacteria, the Fur protein is the major regulator of genes encoding haem- or haemoglobin-binding proteins. Electrophoretic analysis of outer-membrane proteins of the gamma-proteobacterium Pasteurella multocida has revealed the induction of two proteins of 60 and 40 kDa in DPD-treated cultures in both wild-type and fur-defective strains. These two proteins have the same N-terminal amino acid sequence, which identifies this protein as the product of the PM0592 ORF. Analysis of the sequence of this ORF, which encodes a protein of 60 kDa, revealed the presence of a hexanucleotide (AAAAAA) at which a programmed translational frameshift can occur giving rise to a 40 kDa protein. Analyses conducted in Escherichia coli, using the complete PM0592 ORF and a derivative truncated at the hexanucleotide position, have shown that both polypeptides bind haemin. For this reason, the PM0592 ORF product has been designated HbpA (for haemin-binding protein). Expression studies using both RT-PCR and lacZ fusions, as well as electrophoretic profiles of outer-membrane protein composition, have demonstrated that the hbpA gene is negatively regulated by iron, manganese and haemin through a fur-independent pathway. Despite the fact that serum of mice infected with P. multocida contained antibodies that reacted with both the 60 and 40 kDa products of the hbpA gene, these proteins did not offer protection when used in immunization assays against this micro-organism.

Fur is not the global regulator of iron uptake genes in Rhizobium leguminosarum

Rhizobium leguminosarum fur mutants were unaffected in Fe-dependent regulation of several operons that specify different Fe uptake systems, yet cloned R. leguminosarum fur partially corrected an Escherichia coli fur mutant and R. leguminosarum Fur protein bound to canonical fur boxes. The lack of a phenotype in fur mutants is not due to functional redundancy with Irr, another member of the Fur superfamily found in the rhizobia, since irr fur double mutants are also unaffected in Fe-responsive regulation of several operons involved in Fe uptake. Neither Irr nor Fur is needed for symbiotic N(2) fixation on peas. As in Bradyrhizobium japonicum, irr mutants accumulated protoporphyrin IX. R. leguminosarum irr is not regulated by Fur and its Irr protein lacks the motif needed for haem-dependent post-translational modification that occurs in B. japonicum Irr. The similarities and differences in the Fur superfamily in the rhizobia and other Gram-negative bacteria are discussed.

Hemin binding, functional expression, and complementation analysis of Pap 31 from Bartonella henselae

Growth of Bartonella henselae is strongly heme dependent, and B. henselae is unable to synthesize heme itself. At least five outer membrane-associated proteins from B. henselae bind hemin, including the 31-kDa protein designated Pap31. The gene of this protein was heterologously expressed in Escherichia coli M15(pREP4) and detected with monoclonal antibodies in the outer membrane fraction. Complementation of the hemA-deficient mutant E. coli K-12 EB53 (aroB tsx malT hemA) with pap31 demonstrated that this protein is involved in heme acquisition and may be an important virulence factor in the pathogenesis of B. henselae.

RirA, an iron-responsive regulator in the symbiotic bacterium Rhizobium leguminosarum

Mutations in a Rhizobium leguminosarum gene, rirA (rhizobial iron regulator), caused high-level, constitutive expression of at least eight operons whose transcription is normally Fe-responsive and whose products are involved in the synthesis or uptake of siderophores, or in the uptake of haem or of other iron sources. Close homologues of RirA exist in other rhizobia and in the pathogen Brucella; many other bacteria have deduced proteins with more limited sequence similarity. None of these homologues had been implicated in Fe-mediated gene regulation. Transcription of rirA itself is about twofold higher in cells grown in Fe-replete than in Fe-deficient growth media. Mutations in rirA reduced growth rates in Fe-replete and -depleted medium, but did not appear to affect symbiotic N(2) fixation.

Bradyoxetin, a unique chemical signal involved in symbiotic gene regulation

Bradyrhizobium japonicum is a symbiotic bacterium that nodulates soybean. Critical for the infection and establishment of this symbiosis are the bacterial nodulation genes (nod, nol, noe), which are induced in the presence of plant produced isoflavones. Transcription of the nodulation genes is also controlled in a population density-dependent fashion. Expression of the nod genes is maximal at low population densities, and decreases significantly at higher culture densities. Population density control of the nodulation genes involves NolA and NodD2, both of which function in tandem to repress nod gene expression. An extracellular secreted factor (CDF) is known to mediate this repression. Here, we report that CDF is a novel signaling molecule, designated bradyoxetin, different from other Gram-negative quorum signals. The proposed structure of bradyoxetin is 2-[4-[[4-(3-aminooxetan-2-yl)phenyl](imino)methyl]phenyl]oxetan-3-ylamine. Interestingly, expression of bradyoxetin is iron-regulated, and is maximally produced under iron-starved conditions. Consistent with this, expression of the nodulation genes occurred in an iron-dependent fashion. Addition of iron to B. japonicum cultures at high optical densities resulted in decreased bradyoxetin production, and a concomitant reduction in nolA expression. A corresponding increase in nodY-lacZ expression was observed with iron treatment.

Metals and the rhizobial-legume symbiosis--uptake, utilization and signalling

In this review, we consider how the nitrogen-fixing root nodule bacteria, the 'rhizobia', acquire various metals, paying particular attention to the uptake of iron. We also review the literature pertaining to the roles of molybdenum and nickel in the symbiosis with legumes. We highlight some gaps in our knowledge, for example the lack of information on how rhizobia acquire molybdenum. We examine the means whereby different metals affect rhizobial physiology and the role of metals as signals for gene regulation. We describe the ways in which genetics has shown (or not) if, and how, particular metal uptake and/or metal-mediated signalling pathways are required for the symbiotic interaction with legumes.

Interaction between the bacterial iron response regulator and ferrochelatase mediates genetic control of heme biosynthesis

The heme biosynthetic pathway culminates with the insertion of iron into protoporphyrin catalyzed by ferrochelatase. The Bradyrhizobium japonicum iron response regulator (Irr) protein represses the pathway at an early step under iron limitation to prevent protoporphyrin synthesis from exceeding iron availability. Here, we show that Irr interacts directly with ferrochelatase and responds to iron via the status of heme and protoporphyrin localized at the site of heme synthesis. In the presence of iron, ferrochelatase inactivates Irr, followed by heme-dependent Irr degradation to derepress the pathway. Under iron limitation, protoporphyrin relieves the inhibition of Irr by ferrochelatase, probably by promoting protein dissociation, allowing genetic repression. Thus, metabolic control of the heme pathway involves a regulatory function of a biosynthetic enzyme to affect gene expression. Furthermore, heme can serve as a signaling molecule without accumulating freely in cells.

Identification, characterization, and functional analysis of a gene encoding the ferric uptake regulation protein in Bartonella species

Environmental iron concentrations coordinately regulate transcription of genes involved in iron acquisition and virulence via the ferric uptake regulation (fur) system. We identified and sequenced the fur gene and flanking regions of three Bartonella species. The most notable difference between Bartonella Fur and other Fur proteins was a substantially higher predicted isoelectric point. No promoter activity or Fur autoregulation was detected using a gfp reporter gene fused to the 204 nucleotides immediately upstream of the Bartonella fur gene. Bartonella henselae fur gene expression complemented a Vibrio cholerae fur mutant.

Discovery of a haem uptake system in the soil bacterium Bradyrhizobium japonicum

In Bradyrhizobium japonicum, the nitrogen-fixing symbiont of soybeans, we have identified a haem uptake system, Hmu, that comprises a cluster of nine open reading frames. Predicted products of these genes include: HmuR, a TonB-dependent haem receptor in the outer membrane; HmuT, a periplasmic haem-binding protein; and HmuUV, an ABC transporter in the inner membrane. Furthermore, we identified homologues of ExbBD and TonB, that are required for energy transduction from the inner to the outer membrane. Mutant analysis and complementation tests indicated that HmuR and the ExbBD-TonB system, but not the HmuTUV transporter, are essential for haem uptake or haem acquisition from haemoglobin and leghaemoglobin. The TonB system seems to be specific for haem uptake as it is dispensable for siderophore uptake. Therefore, we propose the existence of a second TonB homologue functioning in the uptake of Fe-chelates. When tested on soybean host plants, hmuT-hmuR and exbD-tonB mutants exhibited wild-type symbiotic properties. Thus, haem uptake is not essential for symbiotic nitrogen fixation but it may enable B. japonicum to have access to alternative iron sources in its non-symbiotic state. Transcript analysis and expression studies with lacZ fusions showed that expression of hmuT and hmuR is induced under low iron supply. The same was observed in fur and irr mutant backgrounds although maximal induction levels were decreased. We conclude either that both regulators, Fur and Irr, independently mediate transcriptional control by iron or that a yet unknown iron regulatory system activates gene expression under iron deprivation. An A/T-rich cis-acting element, located in the promoter region of the divergently transcribed hmuTUV and hmuR genes, is possibly required for this type of iron control.

The Burkholderia cepacia fur gene: co-localization with omlA and absence of regulation by iron

The ferric uptake regulator (Fur) functions as a transcription repressor of many genes in bacteria in response to iron, but the presence of a functional equivalent of this protein has not been demonstrated in Burkholderia cepacia. A segment of the Burkholderia pseudomallei fur gene was amplified using degenerate primers and used to identify chromosomal restriction fragments containing the entire fur genes of B. cepacia and B. pseudomallei. These fragments were cloned and sequenced, revealing the Fur protein of both species to be a polypeptide of 142 amino acids possessing a high degree of amino acid sequence identity to Fur of other members of the beta subclass of the Proteobacteria. Primer extension analysis demonstrated that transcription of B. cepacia fur originated from a single promoter located 36 bp upstream from the fur translation initiation codon. The Fur polypeptide of B. cepacia was shown to functionally substitute for Fur in an Escherichia coli fur mutant. Single copy fur-lacZ fusions were constructed and used to examine the regulation of B. cepacia fur. The B. cepacia fur promoter was not responsive to iron availability, the presence of hydrogen peroxide or the superoxide generator methyl viologen. In addition, fur expression was not significantly influenced by carbon source. Interestingly, the presence of the divergently transcribed omlA/smpA gene upstream of fur in some members of the gamma subclass of the Proteobacteria is retained in several genera within the beta taxon, including Burkholderia.

Characterization of the DNA- and metal-binding properties of Vibrio anguillarum fur reveals conservation of a structural Zn(2+) ion

The ferric uptake regulator, Fur, represses iron uptake and siderophore biosynthetic genes under iron-replete conditions. Here we report in vitro solution studies on Vibrio anguillarum Fur binding to the consensus 19-bp Escherichia coli iron box in the presence of several divalent metals. We found that V. anguillarum Fur binds the iron box in the presence of Mn(2+), Co(2+), Cd(2+), and to a lesser extent Ni(2+) but, unlike E. coli Fur, not in the presence of Zn(2+). We also found that V. anguillarum Fur contains a structural zinc ion that is necessary yet alone is insufficient for DNA binding.

Fur-independent regulation of iron metabolism by Irr in Bradyrhizobium japonicum

Bradyrhizobium japonicum expresses both Fur and Irr, proteins that mediate iron-dependent regulation of gene expression. Control of irr mRNA accumulation by iron was aberrant in a fur mutant strain, and Fur repressed an irr::lacZ promoter fusion in the presence of iron. Furthermore, metal-dependent binding of Fur to an irr gene promoter was demonstrated in a region with no significant similarity to the Fur-binding consensus DNA element. These data suggest that the modest control of irr transcription by iron is mediated by Fur. However, Irr protein levels were regulated normally by iron in the fur strain, indicating that Fur is not required for post-transcriptional control of the irr gene. Accordingly, regulation of hemB, a haem biosynthesis gene regulated by Irr, was controlled normally by iron in a fur strain. In addition, the hemA gene was shown to be controlled by Fur, but not by Irr. It was concluded that Fur cannot be the only protein by which B. japonicum cells sense and respond to iron, and that Irr may be involved in Fur-independent signal transduction. Furthermore, iron-dependent regulation of haem biosynthesis involves both Irr and Fur.

Characterization of Vibrio parahaemolyticus manganese-resistant mutants in reference to the function of the ferric uptake regulatory protein

In many bacteria, the ferric uptake regulatory protein (Fur) has a central role in the negative regulation of genes affected by iron limitation. In this study, Vibrio parahaemolyticus strains carrying mutations in the fur gene encoding Fur were isolated by the manganese selection method to assess the function of Fur in connection with alternations in the coordinate expression of the siderophore vibrioferrin (VF) and iron-repressible outer membrane proteins (IROMPs). Ten out of 25 manganese-resistant mutants constitutively produced VF and expressed at least two IROMPs irrespective of the iron concentration in the medium. PCR-direct DNA sequencing of the fur genes in these mutants identified four different point mutations causing amino acid changes. Moreover, a fur overexpressing plasmid was constructed to prepare antiserum against V. parahaemolyticus Fur. Western blotting with this antiserum revealed that the intracellular abundance of the wild-type Fur was not significantly affected by the iron concentrations in the growth medium, and that the Fur proteins of the mutant strains occurred at substantially smaller amounts and/or migrated more rapidly in sodium dodecyl sulfate-polyacrylamide gel electrophoresis than the wild-type Fur. These data afford an additional insight into the structure-function relationship of Fur and imply its involvement in the iron acquisition systems of V. parahaemolyticus, although it is yet unknown whether its action on the target genes is direct or indirect.

Heme is an effector molecule for iron-dependent degradation of the bacterial iron response regulator (Irr) protein

The bacterial iron response regulator (Irr) protein mediates iron-dependent regulation of heme biosynthesis. Pulse-chase and immunoprecipitation experiments showed that Irr degraded in response to 6 microM iron with a half-life of approximately 30 min and that this regulated stability was the principal determinant of control by iron. Irr contains a heme regulatory motif (HRM) near its amino terminus. A role for heme in regulation was implicated by the retention of Irr in heme synthesis mutants in the presence of iron. Addition of heme to low iron (0.3 microM) cultures was sufficient for the disappearance of Irr in cells of the wild-type and heme mutant strains. Spectral and binding analyses of purified recombinant Irr showed that the protein bound heme with high affinity and caused a blue shift in the absorption spectrum of heme to a shorter wavelength. A Cys(29) --> Ala substitution within the HRM of Irr (IrrC29A) abrogated both high affinity binding to heme and the spectral blue shift. In vivo turnover experiments showed that, unlike wild-type Irr, IrrC29A was stable in the presence of iron. We conclude that iron-dependent degradation of Irr involves direct binding of heme to the protein at the HRM. The findings implicate a regulatory role for heme in protein degradation and provide direct evidence for a functional HRM in a prokaryote.