Cloning, sequencing, and characterization of the gene encoding FrpB, a major iron-regulated, outer membrane protein of Neisseria gonorrhoeae.

FrpB (for Fe-regulated protein B) is a 76-kDa outer membrane protein that is part of the iron regulon of Neisseria gonorrhoeae and Neisseria meningitidis. The frpB gene from gonococcal strain FA19 was cloned and sequenced. FrpB was homologous to several TonB-dependent outer membrane receptors of Escherichia coli as well as HemR of Yersinia enterocolitica and CopB of Moraxella catarrhalis. An omga insertion into the frpB coding sequence caused a 60% reduction in 55Fe uptake from heme, but careful analysis suggested that this effect was nonspecific. While FrpB was related to the family of TonB-dependent proteins, a function in iron uptake could not be documented.     

The gene frpB2 of Helicobacter pylori encodes an hemoglobin-binding protein involved in iron acquisition

Human hemoglobin (Hb) is a metalloprotein used by pathogens as a source of iron during invasive process. It can support the Helicobacter pylori growth and several proteins are induced during iron starvation. However, the identity of those proteins remains unknown. In this work, by in silico analysis we identified FrpB2 in H. pylori genome. This protein was annotated as an iron-regulated outer membrane protein. Multiple amino acid alignment showed the motifs necessary for Hb-binding. We demonstrate the ability of FrpB2 to bind Hb by overlay experiments. In addition, the overexpression of this gene allowed the cell growth in media without free iron but supplemented with Hb. All these results support the idea that frpB2 is a gene of H. pylori involved in iron acquisition when Hb is used as a sole iron source.     

Isolation and characterization of an extracellular haem-binding protein from Pseudomonas aeruginosa that shares function and sequence similarities with the Serratia marcescens HasA haemophore

The major mechanism by which bacteria acquire free or haemoglobin-bound haem involves direct binding to specific outer membrane receptors. Serratia marcescens also secretes a haem-binding protein, HasA, which functions as a haemophore that catches haem and shuttles it to a cell surface specific outer membrane receptor, HasR. We report the isolation and characterization of hasAp , a gene from Pseudomonas aeruginosa. HasAp is an iron-regulated extracellular haem-binding protein that shares about 50% identity with HasA. HasAp is required for P. aeruginosa utilization of haemoglobin iron. It can replace HasA for HasR-dependent haemoblobin acquisition in a system reconstituted in Escherichia coli. HasAp, like HasA, lacks a signal peptide and is secreted by an ABC transporter. These findings show that haemophore-dependent haem acquisition is not unique to S. marcescens .     

Haem iron-transport system in enterohaemorrhagic Escherichia coli O157:H7

In this study, we identified the iron-transport systems of Escherichia coli O157:H7 strain EDL933. This strain synthesized and transported enterobactin and had a ferric citrate transport system but lacked the ability to produce or use aerobactin. It used haem and haemoglobin, but not transferrin or lactoferrin, as iron sources. We cloned the gene encoding an iron-regulated haem-transport protein and showed that this E. coli haem-utilization gene ( chuA ) encoded a 69 kDa outer membrane protein that was synthesized in response to iron limitation. Expression of this protein in a laboratory strain of E. coli was sufficient for utilization of haem or haemoglobin as iron sources. Mutation of the chromosomal chuA and tonB genes in E. coli O157:H7 demonstrated that the utilization of haemin and haemoglobin was ChuA- and TonB-dependent. Nucleotide sequence analysis of chuA revealed features characteristic of TonB-dependentFur-regulated, outer membrane iron-transport proteins. It was highly homologous to the shuA gene of Shigella dysenteriae and less closely related to hemR of Yersinia enterocolitica and hmuR of Yersinia pestis . A conserved Fur box was identified upstream of the chuA gene, and regulation by Fur was confirmed.     

Streptococcus pneumoniae secretes a glyceraldehyde-3-phosphate dehydrogenase,which binds haemoglobin and haem

Streptococcus pneumoniae is a gram positive encapsulated bacterium responsible of septicaemia and upper respiratory infections in children. This pathogen requires iron to survive in the host, which it can obtain of haemoglobin (Hb) or haem. Only two Hb-binding membrane proteins have been identified up to now. However it is unknown whether this pathogen secretes proteins in order to scavenge iron from the Hb or haem. Therefore, in order to explore these possibilities, cellular growth of S. pneumoniae was tested with several alternative iron supplies. The bacterial growth was supported with iron, Hb and haem. Additionally, S. pneumoniae expressed and secreted a protein of 38 kDa which was purified and characterized as Hb and haem-binding protein. This protein was also identified by mass spectrometry as glyceraldehyde-3-phosphate dehydrogenase. Our overall results suggest that S. pneumoniae secretes a protein capable of binding two usefull iron sources for this bacterium (Hb and haem). This protein could be playing a dynamic role in the success of the invasive and infective processes of this pathogen.     

Novel nickel transport mechanism across the bacterial outer membrane energized by the TonB/ExbB/ExbD machinery

Nickel is a cofactor for various microbial enzymes, yet as a trace element, its scavenging is challenging. In the case of the pathogen Helicobacter pylori, nickel is essential for the survival in the human stomach, because it is the cofactor of the important virulence factor urease. While nickel transport across the cytoplasmic membrane is accomplished by the nickel permease NixA, the mechanism by which nickel traverses the outer membrane (OM) of this Gram-negative bacterium is unknown. Import of iron-siderophores and cobalamin through the bacterial OM is carried out by specific receptors energized by the TonB/ExbB/ExbD machinery. In this study, we show for the first time that H. pylori utilizes TonB/ExbB/ExbD for nickel uptake in addition to iron acquisition. We have identified the nickel-regulated protein FrpB4, homologous to TonB-dependent proteins, as an OM receptor involved in nickel uptake. We demonstrate that ExbB/ExbD/TonB and FrpB4 deficient bacteria are unable to efficiently scavenge nickel at low pH. This condition mimics those encountered by H. pylori during stomach colonization, under which nickel supply and full urease activity are essential to combat acidity. We anticipate that this nickel scavenging system is not restricted to H. pylori, but will be represented more largely among Gram-negative bacteria.     

Cloning and characterization of the Vibrio cholerae genes encoding the utilization of iron from haemin and haemoglobin

Vibrio cholerae can utilize haemin or haemoglobin as its sole source of iron. Four haem utilization mutants of a classical strain of V. cholerae were isolated. These mutations were complemented with pHUT1, a cosmid clone isolated from a library of wild-type CA401 DNA. Two independent Tn5 insertions into the cloned sequence disrupted function in all of the complemented mutants. Escherichia coli 1017 transformed with pHUT1 failed to utilize haemin as an iron source; a second plasmid containing a different cloned fragment of V. cholerae DNA (pHUT3) was required in addition to pHUT1 to reconstitute the system in E. coli. Minicell analysis and SDS-PAGE of protein fractions indicate that pHUT10 (a subclone of p>HUT1) encodes a 26 kDa inner membrane protein, and pHUT3 encodes a 77 kDa outer membrane protein. Loss of either protein by Tn5 mutagenesis abolishes haem utilization in E. coli. An E. coli hemA mutant that cannot synthesize porphyrins was transformed with the recombinant plasmids to determine whether the plasmids encoded the ability to transport the porphyrin as well as the iron. The transformants grew aerobically in media containing haemin, whereas the parental strain was unable to grow under these conditions. This indicates that V. cholerae haem-iron utilization genes allow transport of the entire haem moiety into the cell.     

Iron acquisition systems in the pathogenic Neisseria

Pathogenic neisseriae have a repertoire of high-affinity iron uptake systems to facilitate acquisition of this essential element in the human host. They possess surface receptor proteins that directly bind the extracellular host iron-binding proteins transferrin and lactoferrin. Alternatively, they have siderophore receptors capable of scavenging iron when exogenous siderophores are present. Released intracellular haem iron present in the form of haemoglobin, haemoglobin-haptoglobin or free haem can be used directly as a source of iron for growth through direct binding by specific surface receptors. Although these receptors may vary in complexity and composition, the key protein involved in the transport of iron (as iron, haem or iron-siderophore) across the outer membrane is a TonB-dependent receptor with an overall structure presumably similar to that determined recently for Escherichia coli FhuA or FepA. The receptors are potentially ideal vaccine targets in view of their critical role in survival in the host. Preliminary pilot studies indicate that transferrin receptor-based vaccines may be protective in humans.     

Emerging strategies in microbial haem capture

Gram-negative pathogenic bacteria have evolved novel strategies to obtain iron from host haem-sequestering proteins. These include the production of specific outer membrane receptors that bind directly to host haem-sequestering proteins, secreted haem-binding proteins (haemophores) that bind haem/haemoglobin/haemopexin and deliver the complex to a bacterial cell surface receptor and bacterial proteases that degrade haem-sequestering proteins. Once removed from haem-sequestering proteins, haem may be transported via the bacterial outer membrane receptor into the cell. Recent studies have begun to define the steps by which haem is removed from bacterial haem proteins and transported into the cell. This review describes recent work on the discovery and characterization of these systems. Reference is also made to the transport of haem in serum (via haemoglobin, haemoglobin/haptoglobin, haemopexin, albumin and lipoproteins) and to mechanisms of iron removal from the haem itself (probably via a haem oxygenase pathway in which the protoporphyrin ring is degraded). Haem protein-receptor interactions are discussed in terms of the criteria that govern protein-protein interactions in general, and connections between haem transport and the emerging field of metal transport via metallochaperones are outlined.     

Haem utilization in Vibrio cholerae involves multiple TonB-dependent haem receptors

Vibrio cholerae has multiple iron transport systems, one of which involves haem uptake through the outer membrane receptor HutA. A hutA mutant had only a slight defect in growth using haemin as the iron source, and we show here that V. cholerae encodes two additional TonB-dependent haem receptors, HutR and HasR. HutR has significant homology to HutA as well as to other outer membrane haem receptors. Membrane fractionation confirmed that HutR is present in the outer membrane. The hutR gene was co-transcribed with the upstream gene ptrB, and expression from the ptrB promoter was negatively regulated by iron. A hutA, hutR mutant was significantly impaired, but not completely defective, in the ability to use haemin as the sole iron source. HasR is most similar to the haemophore-utilizing haem receptors from Pseudomonas aeruginosa and Serratia marcescens. A mutant defective in all three haem receptors was unable to use haemin as an iron source. HutA and HutR functioned with either V. cholerae TonB1 or TonB2, but haemin transport through either receptor was more efficient in strains carrying the tonB1 system genes. In contrast, haemin uptake through HasR was TonB2 dependent. Efficient utilization of haemoglobin as an iron source required HutA and TonB1. The triple haem receptor mutant exhibited no defect in its ability to compete with its Vib- parental strain in an infant mouse model of infection, indicating that additional iron sources are present in vivo. V. cholerae used haem derived from marine invertebrate haemoglobins, suggesting that haem may be available to V. cholerae growing in the marine environment.     

Entamoeba histolytica secretes two haem-binding proteins to scavenge haem

Entamoeba histolytica is a human pathogen which can grow using different sources of iron such as free iron, lactoferrin, transferrin, ferritin or haemoglobin. In the present study, we found that E. histolytica was also capable of supporting its growth in the presence of haem as the sole iron supply. In addition, when trophozoites were maintained in cultures supplemented with haemoglobin as the only iron source, the haem was released and thus it was introduced into cells. Interestingly, the Ehhmbp26 and Ehhmbp45 proteins could be related to the mechanism of iron acquisition in this protozoan, since they were secreted to the medium under iron-starvation conditions, and presented higher binding affinity for haem than for haemoglobin. In addition, both proteins were unable to bind free iron or transferrin in the presence of haem. Taken together, our results suggest that Ehhmbp26 and Ehhmbp45 could function as haemophores, secreted by this parasite to facilitate the scavenging of haem from the host environment during the infective process.     

Transferrin-bipyridine iron transfer mediated by haemoproteins

Rabbit reticulocyte cytosol was able to mediate transferrin-bipyridine iron transfer in the presence of ATP. The cytoplasmic factor responsible for the mediation of iron transfer was identified as haemoglobin. Other cytoplasmic proteins and the membrane fraction were ineffective. Human α and β subunits and human myoglobin were over three times more effective than human haemoglobin A. Carbon monoxide strongly inhibited the mediation of iron transfer. Oxidation of haemoglobin abolished it but methaemoglobin could be reactivated with NADH, even when azide was bound to the haem iron.Neither globin nor haem alone were able to mediate iron transfer, even when NADH was present. Together, the reconstituted methaemoglobin A could be reactivated with NADH.Although the physiological significance of this phenomenon is not clear, the involvement of haemoproteins in intracellular iron metabolism seems likely.     

A putative P-type ATPase required for virulence and resistance to haem toxicity in Listeria monocytogenes

Regulation of iron homeostasis in many pathogens is principally mediated by the ferric uptake regulator, Fur. Since acquisition of iron from the host is essential for the intracellular pathogen Listeria monocytogenes, we predicted the existence of Fur-regulated systems that support infection. We examined the contribution of nine Fur-regulated loci to the pathogenicity of L. monocytogenes in a murine model of infection. While mutating the majority of the genes failed to affect virulence, three mutants exhibited a significantly compromised virulence potential. Most striking was the role of the membrane protein we designate FrvA (Fur regulated virulence factor A; encoded by frvA [lmo0641]), which is absolutely required for the systemic phase of infection in mice and also for virulence in an alternative infection model, the Wax Moth Galleria mellonella. Further analysis of the ΔfrvA mutant revealed poor growth in iron deficient media and inhibition of growth by micromolar concentrations of haem or haemoglobin, a phenotype which may contribute to the attenuated growth of this mutant during infection. Uptake studies indicated that the ΔfrvA mutant is unaffected in the uptake of ferric citrate but demonstrates a significant increase in uptake of haem and haemin. The data suggest a potential role for FrvA as a haem exporter that functions, at least in part, to protect the cell against the potential toxicity of free haem.     

NMR studies of the C-terminal secretion signal of the haem-binding protein, HasA.

HasA is a haem-binding protein which is secreted under iron-deficiency conditions by the gram-negative bacterium Serratia marcescens. It is a monomer of 19 kDa (187 residues) able to bind free haem as well as to capture it from haemoglobin. HasA delivers haem to a specific outer-membrane receptor HasR and allows the bacteria to grow in the absence of any other source of iron. It is secreted by a signal peptide-independent pathway which involves a C-terminal secretion signal and an ABC (ATP-binding cassette) transporter. The C-terminal region of the secretion signal containing the essential secretion motif is cleaved during or after the secretion process by proteases secreted by the bacteria. In this work, we study by 1H NMR the conformation of the C-terminal extremity of HasA in the whole protein and that of the isolated secretion signal peptide in a zwitterionic micelle complex that mimicks the membrane environment. We identify a helical region followed by a random-coil C-terminus in the peptide-micelle complex and we show that in both the whole protein and the complex, the last 15 residues containing the motif essential for secretion are highly flexible and unstructured. This flexibility may be a prerequisite to the recognition of HasA by its ABC transporter. We determine the cleavage site of the C-terminal extremity of the protein and analyse the effect of the cleavage on the haem acquisition process.     

Resonance Raman scattering on the haem group of cytochrome c

Resonance Raman spectra of the haem group of 8 × 10^?5 M horse heart ferro- and ferricytochrome c solutions have been obtained. The spectra are almost identical to that of haemoglobin. The frequency of the Raman line near 1370 cm^?1, which in haemoglobin is sensitive to the position of the haem iron, indicates that the iron atom of cytochrome c lies in the plane of the porphyrin for both oxidation states.     

Acquisition of iron from host sources by mesophilic Aeromonas species.

The mesophilic Aeromonas species are opportunistic pathogens that produce either of the siderophores amonabactin or enterobactin. Acquisition of iron for growth from Fe-transferrin in serum was dependent on the siderophore amonabactin; 50 of 54 amonabactin-producing isolates grew in heat-inactivated serum, whereas none of 30 enterobactin-producing strains were able to grow. Most isolates (regardless of siderophore produced) used haem as a sole source of iron for growth; all of 33 isolates grew with either haematin or haemoglobin and 30 of these used haemoglobin when complexed to human haptoglobin. Mutants unable to synthesize a siderophore used iron from haem, suggesting that this capacity was unrelated to siderophore production. Some members of the mesophilic Aeromonas species have evolved both siderophore-dependent and -independent mechanisms for acquisition of iron from a host.