The Bordetella bhu locus is required for heme iron utilization

Integration of environmental signals controls expression of Bordetella heme utilization genes

The Bordetella pertussis heme utilization gene cluster hurIR bhuRSTUV encodes regulatory and transport functions required for assimilation of iron from heme and hemoproteins. Expression of the bhu genes is iron regulated and heme inducible. The putative extracytoplasmic function (ECF) sigma factor, HurI, is required for heme-responsive bhu gene expression. In this study, transcriptional activation of B. pertussis bhu genes in response to heme compounds was shown to be dose dependent and specific for heme; protoporphyrin IX and other heme structural analogs did not activate bhu gene expression. Two promoters controlling expression of the heme utilization genes were mapped by primer extension analysis. The hurI promoter showed similarity to sigma(70)-like promoters, and its transcriptional activity was iron regulated and heme independent. A second promoter identified upstream of bhuR exhibited little similarity to previously characterized ECF sigma factor-dependent promoters. Expression of bhuR was iron regulated, heme responsive, and hurI dependent in B. pertussis, as shown in a previous study with Bordetella bronchiseptica. Further analyses showed that transcription originating at a distal upstream site and reading through the hurR-bhuR intergenic region contributes to bhuR expression under iron starvation conditions in the absence of heme inducer. The pattern of regulation of the readthrough transcript was consistent with transcription from the hurI promoter. The positions and regulation of the two promoters within the hur-bhu gene cluster influence the production of heme transport machinery so that maximal expression of the bhu genes occurs under iron starvation conditions only in the presence of heme iron sources.

RhuR, an extracytoplasmic function sigma factor activator, is essential for heme-dependent expression of the outer membrane heme and hemoprotein receptor of Bordetella avium

Genes involved in iron (Fe) acquisition often are regulated in response to the local availability of Fe. In many bacteria, Fe-dependent responsiveness is mediated by Fur, a global Fe-dependent transcriptional repressor. Tighter regulatory control of Fur-responsive genes is afforded by incorporating additional regulators into Fur-dependent regulatory cascades. RhuI, a Fur-dependent extracytoplasmic function sigma factor of Bordetella avium, in response to the dual stimulation of Fe starvation and the presence of heme (or hemoproteins), regulates P(bhuR), a heme-responsive promoter which directs expression of the bhuRSTUV heme utilization operon. While BhuR, the outer membrane heme receptor, and RhuI have been shown to be indispensable for heme-dependent activation of P(bhuR), collateral components of the regulatory cascade have not been described. In this investigation, RhuR, an integral cytoplasmic membrane protein with homology to anti-sigma factors, is shown to be an essential activator of P(bhuR) expression. The functional domain of RhuR required for heme-dependent activation of P(bhuR) expression was mapped to the N-terminal 97 amino acids of the protein by use of a chimeric RhuR-BlaM fusion. Expression of the chimera in a rhuR mutant rendered P(bhuR) constitutive, thereby decoupling the promoter from heme dependency. Growth studies confirmed that B. avium requires RhuR for optimal utilization of hemoglobin, but not hemin, as a sole source of nutrient Fe. These data imply that B. avium expresses, in addition to the BhuR heme/hemoprotein utilization system, an alternative RhuR-independent heme utilization mechanism. A model is proposed in which RhuR is the functional bridge between BhuR and RhuI in a heme-dependent regulatory cascade.

Haemophore-mediated signal transduction across the bacterial cell envelope in Serratia marcescens: the inducer and the transported substrate are different molecules

Numerous bacteria are able to use free and haemoprotein-bound haem as iron sources because of the action of small secreted proteins called haemophores. Haemophores have very high affinity for haem, and can therefore extract haem from the haem-carrier proteins and deliver it to the cells by means of specific cell surface receptors. Haem is then taken up and the empty haemophores are recycled. Here, we report a study of the regulation of the Serratia marcescens has operon which is involved in haemophore-dependent haem acquisition. We characterized two genes encoding proteins homologous to specific ECF sigma and antisigma factors. We showed that they regulate the synthesis of the haemophore-specific outer membrane receptor, HasR, by a signal transduction mechanism similar to the siderophore surface-signalling systems. We also showed the essential role of HasR itself in this process. Using haem-loaded and haem-free haemophore, we identified the stimulus for the HasR-mediated signal transduction as being the binding of the haem-loaded haemophore to HasR. Thus, unlike siderophore-uptake systems, in which the signalling molecule is the transported substrate itself, in the haemophore-dependent haem uptake system the inducer and the transported substrate are different compounds.

Regulation of the FecI-type ECF sigma factor by transmembrane signalling

Induction of the ferric citrate transport genes of Escherichia coli K-12 involves a signalling cascade that starts at the cell surface and proceeds to the cytoplasm. Three specific proteins are involved: FecA in the outer membrane, FecR in the cytoplasmic membrane, and FecI in the cytoplasm. The binding of dinuclear ferric citrate to FecA causes substantial structural changes in FecA, triggering the signal cascade. The amino-proximal end of FecA interacts with the carboxy-proximal end of FecR in the periplasm. FecR then transmits the signal across the cytoplasmic membrane into the cytoplasm and activates the FecI sigma factor, which binds to the RNA polymerase core enzyme and directs the RNA polymerase to the promoter upstream of the fecABCDE transport genes to initiate transcription. Transcription of the fecIR regulatory genes and the fec transport genes is repressed by the Fur protein loaded with Fe(2+). Therefore, transcription of the fec transport genes is subjected to double control: cells first detect iron deficiency and respond by synthesis of the regulatory proteins FecI and FecR, which initiate transcription of the fec transport genes, provided ferric citrate is available. FecI belongs to the extracytoplasmic function sigma factors, which are widespread among bacteria. With the recent sequencing of complete microbial genomes, it has become apparent that the FecIRA cascade is now a paradigm for the regulatory control of FecI family sigmas in Gram-negative bacteria.

Heme-responsive transcriptional activation of Bordetella bhu genes

Bordetella pertussis and Bordetella bronchiseptica, gram-negative respiratory pathogens of mammals, possess a heme iron utilization system encoded by the bhuRSTUV genes. Preliminary evidence suggested that expression of the BhuR heme receptor was stimulated by the presence of heme under iron-limiting conditions. The hurIR (heme uptake regulator) genes were previously identified upstream of the bhuRSTUV gene cluster and are predicted to encode homologs of members of the iron starvation subfamily of extracytoplasmic function (ECF) regulators. In this study, B. pertussis and B. bronchiseptica DeltahurI mutants, predicted to lack an ECF sigma factor, were constructed and found to be deficient in the utilization of hemin and hemoglobin. Genetic complementation of DeltahurI strains with plasmid-borne hurI restored wild-type levels of heme utilization. B. bronchiseptica DeltahurI mutant BRM23 was defective in heme-responsive production of the BhuR heme receptor; hurI in trans restored heme-inducible BhuR expression to the mutant and resulted in BhuR overproduction. Transcriptional analyses with bhuR-lacZ fusion plasmids confirmed that bhuR transcription was activated in iron-starved cells in response to heme compounds. Heme-responsive bhuR transcription was not observed in mutant BRM23, indicating that hurI is required for positive regulation of bhu gene expression. Furthermore, bhuR was required for heme-inducible bhu gene activation, supporting the hypothesis that positive regulation of bhuRSTUV occurs by a surface signaling mechanism involving the heme-iron receptor BhuR.

Iron transport and signaling in Escherichia coli

Bacteria solve the iron supply problem caused by the insolubility of Fe(3+) by synthesizing iron-complexing compounds, called siderophores, and by using iron sources of their hosts, such as heme and iron bound to transferrin and lactoferrin. Escherichia coli, as an example of Gram-negative bacteria, forms sophisticated Fe(3+)-siderophore and heme transport systems across the outer membrane. The crystal structures of three outer membrane transport proteins now allow insights into energy-coupled transport mechanisms. These involve large long-range structural transitions in the transport proteins in response to substrate binding, including substrate gating. Energy is provided by the proton motive force of the cytoplasmic membrane through the activity of a protein complex that is inserted in the cytoplasmic membrane and that contacts the outer membrane transporters. Certain transport proteins also function in siderophore-mediated signaling cascades that start at the cell surface and flow to the cytoplasm to initiate transcription of genes encoding proteins for transport and siderophore biosynthesis.

BhuR, a virulence-associated outer membrane protein of Bordetella avium, is required for the acquisition of iron from heme and hemoproteins

Iron (Fe) is an essential element for most organisms which must be obtained from the local environment. In the case of pathogenic bacteria, this fundamental element must be acquired from the fluids and tissues of the infected host. A variety of systems have evolved in bacteria for efficient acquisition of host-bound Fe. The gram-negative bacterium Bordetella avium, upon colonization of the avian upper respiratory tract, produces a disease in birds that has striking similarity to whooping cough, a disease caused by the obligate human pathogen Bordetella pertussis. We describe a B. avium Fe utilization locus comprised of bhuR and six accessory genes (rhuIR and bhuSTUV). Genetic manipulations of B. avium confirmed that bhuR, which encodes a putative outer membrane heme receptor, mediates efficient acquisition of Fe from hemin and hemoproteins (hemoglobin, myoglobin, and catalase). BhuR contains motifs which are common to bacterial heme receptors, including a consensus FRAP domain, an NPNL domain, and two TonB boxes. An N-terminal 32-amino-acid segment, putatively required for rhuIR-dependent regulated expression of bhuR, is present in BhuR but not in other bacterial heme receptors. Two forms of BhuR were observed in the outer membrane of B. avium: a 91-kDa polypeptide consistent in size with the predicted mature protein and a smaller 82-kDa polypeptide which lacks the 104 amino acids found at the N terminus of the 91-kDa form. A mutation in hemA was engineered in B. avium to demonstrate that the bacterium transports heme into the cytoplasm in a BhuR-dependent manner. The role of BhuR in virulence was established in turkey poults by use of a competitive-infection model.

Functional interaction of region 4 of the extracytoplasmic function sigma factor FecI with the cytoplasmic portion of the FecR transmembrane protein of the Escherichia coli ferric citrate transport system

Transcriptional regulation of the ferric citrate transport genes of Escherichia coli is initiated by the binding of ferric citrate to the outer membrane protein FecA. This binding elicits a signal that is transmitted by FecR across the cytoplasmic membrane into the cytoplasm, where the sigma factor FecI directs the RNA polymerase to the promoter upstream of the fecABCDE genes. An in vivo deletion analysis using a bacterial two-hybrid system assigned the interaction of the FecR and FecI proteins to the cytoplasmic portion of the FecR transmembrane protein and region 4 of FecI. Missense mutations randomly generated by PCR were localized to region 4 of FecI, and the mutants were impaired with regard to the interaction of FecR with FecI and fecB-lacZ transcription. The cloned region 4 of FecI interfered with fecB-lacZ transcription. Interaction of N-proximal regions of predicted FecR homologs with region 4 of predicted FecI homologs of Pseudomonas aeruginosa was demonstrated. The interaction was specific in that only cognate protein pairs interacted with each other; no interactions occurred between heterologous combinations of the P. aeruginosa proteins and between a P. aeruginosa FecI homolog and E. coli FecR. The results demonstrate that region 4 of FecI specifically binds FecR and that this binding is necessary for FecI to function as a sigma factor.

Bordetella interspecies allelic variation in AlcR inducer requirements: identification of a critical determinant of AlcR inducer responsiveness and construction of an alcR(Con) mutant allele

Previous studies established the critical roles of AlcR and alcaligin inducer in positive regulation of alcaligin siderophore biosynthesis and transport genes in Bordetella pertussis and Bordetella bronchiseptica. Transcriptional analyses using plasmid-borne alcR genes of B. pertussis UT25 and B. bronchiseptica B013N to complement the alcR defect of B. bronchiseptica strain BRM13 (Delta alcR1 alcA::mini-Tn5 lacZ1) revealed interspecies differences in AlcR inducer requirements for activation of alcABCDER operon transcription. Whereas the B. pertussis UT25 AlcR protein retained strong inducer dependence when produced from multicopy plasmids, B. bronchiseptica B013N alcR partially suppressed the alcaligin requirement for transcriptional activation. Functional analysis of AlcR chimeras produced by interspecies domain swapping and interspecies reciprocal site-specific mutagenesis determined that the phenotypic difference in AlcR inducer dependence was due to a single amino acid difference within the proposed inducer-binding and multimerization domain of AlcR. Structural predictions guided the design of a mutant AlcR protein with a single amino acid substitution at this critical position, AlcR(S103T), that was fully constitutive not only when produced from multicopy plasmids but also at a single-copy gene dosage. These results indicate that AlcR residue 103 affects a critical determinant of alcaligin inducer dependence of AlcR-mediated transcriptional activation. The alcR(S103T) mutant allele is the first alcR(Con) mutant allele identified.

Heme utilization in Bordetella avium is regulated by RhuI, a heme-responsive extracytoplasmic function sigma factor

Efficient utilization of heme as an iron (Fe) source by Bordetella avium requires bhuR, an Fe-regulated gene which encodes an outer membrane heme receptor. Upstream of bhuR is a 507-bp open reading frame, hereby designated rhuI (for regulator of heme uptake), which codes for a 19-kDa polypeptide. Whereas the 19-kDa polypeptide had homology to a subfamily of alternative sigma factors known as the extracytoplasmic function (ECF) sigma factors, it was hypothesized that rhuI encoded a potential in-trans regulator of the heme receptor gene in trans. Support for the model was strengthened by the identification of nucleotide sequences common to ECF sigma-dependent promoters in the region immediately upstream of bhuR. Experimental evidence for the regulatory activities of rhuI was first revealed by recombinant experiments in which overproduction of rhuI was correlated with a dramatically increased expression of BhuR. A putative rhuI-dependent bhuR promoter was identified in the 199-bp region located proximal to bhuR. When a transcriptional fusion of the 199-bp region and a promoterless lacZ gene was introduced into Escherichia coli, promoter activity was evident, but only when rhuI was coexpressed in the cell. Sigma competition experiments in E. coli demonstrated that rhuI conferred biological properties on the cell that were consistent with RhuI having sigma factor activity. Heme, hemoglobin, and several other heme-containing proteins were shown to be the extracellular inducers of the rhuI-dependent regulatory system. Fur titration assays indicated that expression of rhuI was probably Fur dependent.