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.     

Passively released heme from hemoglobin and myoglobin is a potential source of nutrient iron for Bordetella bronchiseptica

Colonization by Bordetella bronchiseptica results in a variety of inflammatory respiratory infections, including canine kennel cough, porcine atrophic rhinitis, and a whooping cough-like disease in humans. For successful colonization, B. bronchiseptica must acquire iron (Fe) from the infected host. A vast amount of Fe within the host is sequestered within heme, a metalloporphyrin which is coordinately bound in hemoglobin and myoglobin. Utilization of hemoglobin and myoglobin as sources of nutrient Fe by B. bronchiseptica requires expression of BhuR, an outer membrane protein. We hypothesize that hemin is acquired by B. bronchiseptica in a BhuR-dependent manner after spontaneous loss of the metalloporphyrin from hemoglobin and/or myoglobin. Sequestration experiments demonstrated that direct contact with hemoglobin or myoglobin was not required to support growth of B. bronchiseptica in an Fe-limiting environment. Mutant myoglobins, each exhibiting a different affinity for heme, were employed to demonstrate that the rate of growth of B. bronchiseptica was directly correlated with the rate at which heme was lost from the hemoprotein. Finally, Escherichia coli cells expressing recombinant BhuR had the capacity to remove hemin from solution. Collectively, these experiments provided strong experimental support for the model that BhuR is a hemin receptor and B. bronchiseptica likely acquires heme during infection after passive loss of the metalloporphyrin from hemoglobin and/or myoglobin. These results also suggest that spontaneous hemin loss by hemoglobin and myoglobin may be a common mechanism by which many pathogenic bacteria acquire heme and heme-bound Fe.     

Overcoming the Heme Paradox: Heme Toxicity and Tolerance in Bacterial Pathogens

Virtually all bacterial pathogens require iron to infect vertebrates. The most abundant source of iron within vertebrates is in the form of heme as a cofactor of hemoproteins. Many bacterial pathogens have elegant systems dedicated to the acquisition of heme from host hemoproteins. Once internalized, heme is either degraded to release free iron or used intact as a cofactor in catalases, cytochromes, and other bacterial hemoproteins. Paradoxically, the high redox potential of heme makes it a liability, as heme is toxic at high concentrations. Although a variety of mechanisms have been proposed to explain heme toxicity, the mechanisms by which heme kills bacteria are not well understood. Nonetheless, bacteria employ various strategies to protect against and eliminate heme toxicity. Factors involved in heme acquisition and detoxification have been found to contribute to virulence, underscoring the physiological relevance of heme stress during pathogenesis. Herein we describe the current understanding of the mechanisms of heme toxicity and how bacterial pathogens overcome the heme paradox during infection.Iron is an essential cofactor for many enzymes found within all kingdoms of life. Bacterial pathogens are no exception to this rule, and therefore, they must acquire iron from their hosts in order to cause disease. Iron is a transition metal that can cycle between redox states, making it a valuable cofactor for biological processes. Ferric iron is water insoluble, and as such, it requires specialized proteins to facilitate its mobilization and to maintain intracellular reservoirs. In mammalian species, lactoferrin and transferrin transport iron, while ferritin stores iron. The most abundant form of iron in vertebrates, however, is bound within a porphyrin ring as ferriprotoporphyrin IX (heme). Heme solubilizes iron and enhances its catalytic ability by 5 to 10 orders of magnitude (14, 111). This catalytic activity is harnessed by hemoproteins involved in oxygenation reactions, oxidative stress responses, electron transport, oxygen transport, oxygen sensing, and oxygen storage. While heme is a necessary prosthetic group for many proteins, it also has the potential to cause toxicity at high concentrations. This property of heme requires that the intracellular pool of heme be tightly regulated.Intracellular heme concentrations within vertebrates are tightly controlled by balancing the rates of heme biosynthesis and catabolism (87). Free heme released into the plasma by the dissolution of hemoproteins from lysed erythrocytes is quickly scavenged by albumin, hemopexin, and the serum lipocalin α₁-microglobulin (13, 23, 44, 75). Any hemoglobin released into the serum is tightly bound by haptoglobin and subsequently cleared by tissue macrophages (51). It is evident that the vital yet reactive nature of heme requires that its production, degradation, and availability be carefully controlled in metazoans. Meeting these demands reduces heme-mediated toxicity and minimizes surplus free heme. Most bacterial pathogens that infect vertebrate tissues have systems dedicated to the acquisition of heme for use as a nutrient iron source. However, the toxicity of heme presents a paradox for microorganisms that satisfy their nutrient iron requirement through heme acquisition. This heme paradox is resolved through tightly regulated systems dedicated to balancing the acquisition of heme with the prevention of heme-mediated toxicity.     

Multiple NADPH-cytochrome P450 reductases from Trypanosoma cruzi suggested role on drug resistance

Cytochrome P450 hemoproteins (CYPs) are involved in the synthesis of endogenous compounds such as steroids, fatty acids and prostaglandins as well as in the activation and detoxification of foreign compounds including therapeutic drugs. Cytochrome P450 reductase (CPR, E.C.1.6.2.4) transfers electrons from NADPH to a number of hemoproteins such as CYPs, cytochrome c, cytochrome b5, and heme oxygenase. This work presents the complete sequences of three non-allelic CPR genes from Trypanosoma cruzi. The encoded proteins named TcCPR-A, TcCPR-B and TcCPR-C have calculated molecular masses of 68.6kDa, 78.4kDa and 71.3kDa, respectively. Deduced amino acid sequences share 11% amino acid identity, possess the conserved binding domains for FMN, FAD and NADPH and differ in the hydrophobic 27-amino acid residues of the N-terminal extension, which is absent in TcCPR-A. Every T. cruzi CPRs, TcCPR-A, TcCPR-B and TcCPR-C, were cloned and expressed in Escherichia coli. All of the recombinant enzymes reduced cytochrome c in a NADPH absolutely dependent manner with low K(m) values for this cofactor. They all were also strongly inhibited by diphenyleneiodonium, a classical flavoenzyme inhibitor. In addition, TcCPRs could support CYP activities when assayed in reconstituted systems containing rat liver microsomes. Polyclonal antiserum rose against the recombinant enzymes TcCPR-A and TcCPR-B demonstrated its presence in every T. cruzi developmental stages, with a remarkable expression of TcCPR-A in cell-cultured trypomastigotes. Overexpression of TcCPR-B in T. cruzi epimastigotes increased its resistance to the typical chemotherapeutic agents Nifurtimox and Benznidazole. We suggest a participation of TcCPR-B in the detoxification metabolism of the parasite.     

Identification of shuA, the gene encoding the heme receptor of Shigella dysenteriae, and analysis of invasion and intracellular multiplication of a shuA mutant.

shuA encodes a 70-kDa outer membrane heme receptor in Shigella dysenteriae. Analysis of the shuA DNA sequence indicates that this gene encodes a protein with homology to TonB-dependent receptors of gram-negative bacteria. Transport of heme by the ShuA protein requires TonB and its accessory proteins ExbB and ExbD. The shuA DNA sequence contains a putative Fur box overlapping the -10 region of a potential shuA promoter, and the expression of shuA is repressed by exogenous iron or hemin in a Fur-dependent manner, although hemin repressed expression to a lesser extent than iron salts. Disruption of this open reading frame on the S. dysenteriae chromosome by marker exchange yielded a strain that failed to use heme as an iron source, indicating that shuA is essential for heme transport in S. dysenteriae. However, shuA is not essential for invasion or multiplication within cultured Henle cells; the shuA mutant invaded and produced normal plaques in confluent cell monolayers.     

The Neisseria meningitidis ZnuD zinc receptor contributes to interactions with epithelial cells and supports heme utilization when expressed in Escherichia coli

Neisseria meningitidis employs redundant heme acquisition mechanisms, including TonB receptor-dependent and receptor-independent uptakes. The TonB-dependent zinc receptor ZnuD shares significant sequence similarity to HumA, a heme receptor of Moraxella catarrhalis, and contains conserved motifs found in many heme utilization proteins. We present data showing that, when expressed in Escherichia coli, ZnuD allowed heme capture on the cell surface and supported the heme-dependent growth of an E. coli hemA strain. Heme agarose captured ZnuD in enriched outer membrane fractions, and this binding was inhibited by excess free heme, supporting ZnuD's specific interaction with heme. However, no heme utilization defect was detected in the meningococcal znuD mutant, likely due to unknown redundant TonB-independent heme uptake mechanisms. Meningococcal replication within epithelial cells requires a functional TonB, and we found that both the znuD and tonB mutants were defective not only in survival within epithelial cells but also in adherence to and invasion of epithelial cells. Ectopic complementation rescued these phenotypes. Interestingly, while znuD expression was repressed by Zur with zinc as a cofactor, it also was induced by iron in a Zur-independent manner. A specific interaction of meningococcal Fur protein with the znuD promoter was demonstrated by electrophoretic mobility shift assay (EMSA). Thus, the meningococcal ZnuD receptor likely participates in both zinc and heme acquisition, is regulated by both Zur and Fur, and is important for meningococcal interaction with epithelial cells.