Ferredoxin-NADP+ Reductase from Pseudomonas putida Functions as a Ferric Reductase

Pseudomonas putida harbors two ferredoxin-NADP⁺ reductases (Fprs) on its chromosome, and their functions remain largely unknown. Ferric reductase is structurally contained within the Fpr superfamily. Interestingly, ferric reductase is not annotated on the chromosome of P. putida. In an effort to elucidate the function of the Fpr as a ferric reductase, we used a variety of biochemical and physiological methods using the wild-type and mutant strains. In both the ferric reductase and flavin reductase assays, FprA and FprB preferentially used NADPH and NADH as electron donors, respectively. Two Fprs prefer a native ferric chelator to a synthetic ferric chelator and utilize free flavin mononucleotide (FMN) as an electron carrier. FprB has a higher k_cat/K_m value for reducing the ferric complex with free FMN. The growth rate of the fprB mutant was reduced more profoundly than that of the fprA mutant, the growth rate of which is also lower than the wild type in ferric iron-containing minimal media. Flavin reductase activity was diminished completely when the cell extracts of the fprB mutant plus NADH were utilized, but not the fprA mutant with NADPH. This indicates that other NADPH-dependent flavin reductases may exist. Interestingly, the structure of the NAD(P) region of FprB, but not of FprA, resembled the ferric reductase (Fre) of Escherichia coli in the homology modeling. This study demonstrates, for the first time, the functions of Fprs in P. putida as flavin and ferric reductases. Furthermore, our results indicated that FprB may perform a crucial role as a NADH-dependent ferric/flavin reductase under iron stress conditions.Commonly, Fprs are ubiquitous, monomeric, reversible flavin enzymes. Fprs evidence a profound preference for NADP(H) over NAD(H) (3). They harbor a prosthetic flavin cofactor (FAD) and catalyze the reversible electron exchange between NADPH and either ferredoxin (Fd) or flavodoxin (Fld) (4, 5). In oxygenic photosynthesis, the Fd is reduced by the photosystem and subsequently passes electrons on to NADP⁺ via the Fpr. This reaction provides the cellular NADPH pool required for CO₂ assimilation and other biosynthetic processes (4, 5). In heterotrophic organisms such as bacteria, reduced ferredoxin, owing to the reverse enzymatic activity of the Fpr, can donate an electron to several Fd-dependent enzymes, such as nitrite reductase, sulfite reductase, glutamate synthase, and Fd-thioredoxin reductase, allowing ferredoxin to function in a variety of systems, including oxidative stress (1, 4, 5).Iron is the fourth most abundant element in the natural environment and exists primarily as an oxidized form, Fe(III), which has very low solubility under neutral pH conditions (9, 34) and thus presents problems in terms of bioavailability. However, ferrous iron, of Fe(II), is soluble and available at neutral pH in bacterial cytosol (34). Most bacteria secrete siderophores, which are natural chelators of ferric iron. After they bind to ferric iron, that complex enters the bacteria and releases ferric iron into the cytosol in ferric or ferrous form (9). In the bacterial cytosol, ferric iron must be reduced to ferrous form, and thus ferric reductase is essential to bacterial iron utilization.Commonly, prokaryotic ferric reductases are divided into two groups—namely, the bacterial and archaeal types (34). The typical bacterial type ferric reductase is Escherichia coli Fre, which also functions as a flavin reductase. In other words, the ferric reductase can reduce free flavin as flavin reductase, rather than having the flavin cofactor as a prosthetic group in E. coli (38). The archaeal ferric reductase harbors a flavin cofactor in the enzyme and thus does not require a flavin carrier for ferric reduction (26, 34). E. coli Fre includes a Rosmann folding structure at the NAD(P) binding region, whereas the archaeal ferric reductase (FeR) of Archaeoglobus fulgidus does not evidence that folding structure (6, 34). Many bacterial ferric reductases utilize free flavins, such as flavin mononucleotide (FMN), flavin adenine dinucleotide (FAD) and riboflavin, as electron carrier and, NADH (NAD) or NADP as electron donors to ferric reductase (14, 34). However, reduced ferric iron by reduced free flavin gives rise to the Fenton reaction, which generates the hydroxyl radical within the cell (20, 38). The Fenton reaction is known to generate hydroxyl radicals from ferrous iron and hydrogen peroxide (20). The hydroxyl radical is the most reactive radical and can damage DNA, proteins, and membrane lipids (16, 20, 34, 38). Therefore, the fine-tuning of ferric reduction regulation is required for the survival of bacterial cells.Many Pseudomonas strains, including Pseudomonas putida, a gram-negative soil model bacteria, and Pseudomonas aeruginosa, a human pathogen bacteria, do not harbor annotated ferric reductase within their genome sequences. Commonly, the pathogens compete with the host for available iron, whichis crucial for their survival within the host. Thus, studies of P. aeruginosa regarding iron utilization, siderophores, and ferric reduction are considered to be essential for a better understanding of human infections (9, 19). Studying the physiology and ecology of P. putida also provides us with a new framework for elucidating the basis of the metabolic versatility and environmental stress response of soil microorganisms. Thus, the study of ferric reductase in strains of Pseudomonas at the molecular level is certainly required. From the structural perspective, ferric reductases are generally considered to be contained within the structurally diverse ferredoxin-NADP⁺ reductase (Fprs; EC 1.18.1.2) superfamily, which is frequently involved in the transfer of electrons between Fd/Fld and NADP(H) (2, 15, 34). Thus, we tested the role of the Fpr as a ferric reductase using free flavin (FMN or FAD), NADH, or NADPH as electron donors, and ferric-citrate or ferric-EDTA as terminal electron acceptors (37). We determined that FprA could efficiently utilize NADPH in ferric reduction. Rather, FprB could use NADH as an electron donor and may perform a crucial role as a NADH-dependent ferric reductase under iron stress conditions.     

FERRIC CHELATE REDUCTASE ACTIVITY AS AFFECTED BY THE IRON‐LIMITED GROWTH RATE IN FOUR SPECIES OF UNICELLULAR GREEN ALGAE (CHLOROPHYTA)1

Four species of green algae (Chlorella kessleri Fott et Nováková, Chlorococcum macrostigmatum Starr, Haematococcus lacustris[Girod‐Chantrans] Rostaf., Stichococcus bacillaris Näg.) were grown in iron‐limited chemostats and under phosphate limitation and iron (nutrient) sufficiency. For all four species, steady‐state culture density declined with decreasing degree of iron limitation (increasing iron‐limited growth rate), whereas chl per cell or biovolume increased. Plasma membrane ferric chelate reductase activity was enhanced by iron limitation in all species and suppressed by phosphate limitation and iron sufficiency. These results confirm previous work that C. kessleri uses a reductive mechanism of iron acquisition and also suggest that the other three species use the same mechanism. Although imposition of iron limitation led to enhanced activities of ferric chelate reductase in all species, the relationship between ferric chelate reductase activity and degree of iron limitation varied. Ferric chelate reductase activity in C. macrostigmatum and S. bacillaris was an inverse function of the degree of iron limitation, with the most rapidly growing iron‐limited cells exhibiting the highest ferric chelate reductase activity. In contrast, ferric chelate reductase activity was only weakly affected by the degree of iron limitation in C. kessleri and H. lacustris. Calculation of ferric reductase activity per unit chl allowed a clear differentiation between iron‐limited and iron‐sufficient cells. The possible extension of the ferric chelate reductase assay to investigate the absence or presence of iron limitation in natural waters may be feasible, but it is unlikely that the assay could be used to estimate the degree of iron limitation.     

Catalase Expression Is Modulated by Vancomycin and Ciprofloxacin and Influences the Formation of Free Radicals in Staphylococcus aureus Cultures

Detection of free radicals in biological systems is challenging due to their short half-lives. We have applied electron spin resonance (ESR) spectroscopy combined with spin traps using the probes PBN (N-tert-butyl-α-phenylnitrone) and DMPO (5,5-dimethyl-1-pyrroline N-oxide) to assess free radical formation in the human pathogen Staphylococcus aureus treated with a bactericidal antibiotic, vancomycin or ciprofloxacin. While we were unable to detect ESR signals in bacterial cells, hydroxyl radicals were observed in the supernatant of bacterial cell cultures. Surprisingly, the strongest signal was detected in broth medium without bacterial cells present and it was mitigated by iron chelation or by addition of catalase, which catalyzes the decomposition of hydrogen peroxide to water and oxygen. This suggests that the signal originates from hydroxyl radicals formed by the Fenton reaction, in which iron is oxidized by hydrogen peroxide. Previously, hydroxyl radicals have been proposed to be generated within bacterial cells in response to bactericidal antibiotics. We found that when S. aureus was exposed to vancomycin or ciprofloxacin, hydroxyl radical formation in the broth was indeed increased compared to the level seen with untreated bacterial cells. However, S. aureus cells express catalase, and the antibiotic-mediated increase in hydroxyl radical formation was correlated with reduced katA expression and catalase activity in the presence of either antibiotic. Therefore, our results show that in S. aureus, bactericidal antibiotics modulate catalase expression, which in turn influences the formation of free radicals in the surrounding broth medium. If similar regulation is found in other bacterial species, it might explain why bactericidal antibiotics are perceived as inducing formation of free radicals.     

Phenazines and Other Redox-Active Antibiotics Promote Microbial Mineral Reduction

Natural products with important therapeutic properties are known to be produced by a variety of soil bacteria, yet the ecological function of these compounds is not well understood. Here we show that phenazines and other redox-active antibiotics can promote microbial mineral reduction. Pseudomonas chlororaphis PCL1391, a root isolate that produces phenazine-1-carboxamide (PCN), is able to reductively dissolve poorly crystalline iron and manganese oxides, whereas a strain carrying a mutation in one of the phenazine-biosynthetic genes (phzB) is not; the addition of purified PCN restores this ability to the mutant strain. The small amount of PCN produced relative to the large amount of ferric iron reduced in cultures of P. chlororaphis implies that PCN is recycled multiple times; moreover, poorly crystalline iron (hydr)oxide can be reduced abiotically by reduced PCN. This ability suggests that PCN functions as an electron shuttle rather than an iron chelator, a finding that is consistent with the observation that dissolved ferric iron is undetectable in culture fluids. Multiple phenazines and the glycopeptidic antibiotic bleomycin can also stimulate mineral reduction by the dissimilatory iron-reducing bacterium Shewanella oneidensis MR1. Because diverse bacterial strains that cannot grow on iron can reduce phenazines, and because thermodynamic calculations suggest that phenazines have lower redox potentials than those of poorly crystalline iron (hydr)oxides in a range of relevant environmental pH (5 to 9), we suggest that natural products like phenazines may promote microbial mineral reduction in the environment.     

Human transferrin as a source of iron for Streptococcus intermedius

Streptococcus intermedius is well known to produce severe infections in various areas of the body. In this study, we evaluated the ability of S. intermedius to utilise human transferrin as a source of iron and investigated the mechanism by which iron can be obtained from this plasma protein. Adding either ferrous sulfate or holotransferrin to an iron-deficient culture medium allowed growth of S. intermedius. Cultivation of S. intermedius under an iron-poor condition was associated with the over expression of a 58 kDa cell surface protein. Neither siderophore activity nor reductase activity could be detected. Moreover, cells of S. intermedius did not show transferrin-binding activity or proteolytic activity toward transferrin. It was found that S. intermedius could rapidly decrease the pH of the medium during cell growth, resulting in a release of iron from holotransferrin. When the buffering capacity of the culture medium was significantly increased, the holotransferrin could not support growth of S. intermedius. It is suggested that under certain circumstances, S. intermedius may migrate from its normal niche (oral cavity), reach a particular site and create a localised environment where the pH can be lowered with the subsequent release of iron from transferrin. This would allow bacterial growth and initiation of the infectious process.     

Energy Transduction by Anaerobic Ferric Iron Respiration in Thiobacillus ferrooxidans

Formate-grown cells of the obligately chemolithoautotrophic acidophile Thiobacillus ferrooxidans were capable of formate- and elemental sulfur-dependent reduction of ferric iron under anaerobic conditions. Under aerobic conditions, both oxygen and ferric iron could be simultaneously used as electron acceptors. To investigate whether anaerobic ferric iron respiration by T. ferrooxidans is an energy-transducing process, uptake of amino acids was studied. Glycine uptake by starved cells did not occur in the absence of an electron donor, neither under aerobic conditions nor under anaerobic conditions. Uptake of glycine could be driven by formate- and ferrous iron-dependent oxygen uptake. Under anaerobic conditions, ferric iron respiration with the electron donors formate and elemental sulfur could energize glycine uptake. Glycine uptake was inhibited by the uncoupler 2,4-dinitrophenol. The results indicate that anaerobic ferric iron respiration can contribute to the energy budget of T. ferrooxidans.     

“Pseudo” γ-Butyrolactone Receptors Respond to Antibiotic Signals to Coordinate Antibiotic Biosynthesis

In actinomycetes, the onset of secondary metabolite biosynthesis is often triggered by the quorum-sensing signal γ-butyrolactones (GBLs) via specific binding to their cognate receptors. However, the presence of multiple putative GBL receptor homologues in the genome suggests the existence of an alternative regulatory mechanism. Here, in the model streptomycete Streptomyces coelicolor, ScbR2 (SCO6286, a homologue of GBL receptor) is shown not to bind the endogenous GBL molecule SCB1, hence designated “pseudo” GBL receptor. Intriguingly, it could bind the endogenous antibiotics actinorhodin and undecylprodigiosin as ligands, leading to the derepression of KasO, an activator of a cryptic type I polyketide synthase gene cluster. Likewise, JadR2 is also a putative GBL receptor homologue in Streptomyces venezuelae, the producer of chloramphenicol and cryptic antibiotic jadomycin. It is shown to coordinate their biosynthesis via direct repression of JadR1, which activates jadomycin biosynthesis while repressing chloramphenicol biosynthesis directly. Like ScbR2, JadR2 could also bind these two disparate antibiotics, and the interactions lead to the derepression of jadR1. The antibiotic responding activities of these pseudo GBL receptors were further demonstrated in vivo using the lux reporter system. Overall, these results suggest that pseudo GBL receptors play a novel role to coordinate antibiotic biosynthesis by binding and responding to antibiotics signals. Such an antibiotic-mediated regulatory mechanism could be a general strategy to coordinate antibiotic biosynthesis in the producing bacteria.     

Is ethylene involved in regulation of root ferric reductase activity of dicotyledonous species under iron deficiency?

Most dicotyledonous species respond to Fe deficiency by developing some mechanisms known as Fe-deficiency responses. The role of ethylene in regulation of root ferric reductase activity of wild-type tomato (Lycopersicon esculentum L.) and its mutant Never ripe (Nr), bean (Phaseolus vulgaris L., cv. Bifeng 80-30), and cucumber (Cucumis sativus L., cv. Xintaimici) plants grown in nutrient solution without Fe supply was studied under controlled condition. The results show that: (i) the tomato mutant Nr, which is insensitive to ethylene, presented rapid increase in root ferric reductase activity after omitting Fe from the nutrient solution; (ii) the initial time for increase in root ferric reductase activity was earlier than that in ethylene production after onset of Fe deficiency in the three species; (iii) like cobalt (3 μM Co²⁺), an inhibitor for ethylene production, high concentration of zinc (50 μM Zn²⁺) and copper (5 μM Cu²⁺) also suppressed the increase in root ferric reductase activity of Fe-starved plants; (iv) under Fe-sufficient conditions, indol-3-butylric acid (IBA) stimulated root ferric reductase activity of cucumber and bean plants, and this stimulating effect could not be suppressed by aminoethoxyvinylglycine (AVG, an inhibitor for ethylene synthesis). These results suggested that ethylene might not be directly involved in the regulation of root ferric reductase activity of Fe-deficient dicotyledonous species.     

Synthesis of conjugates between oxazolidinone antibiotics and a pyochelin analogue

Pseudomonas aeruginosa is a Gram-negative pathogenic bacterium responsible for severe infections, and it is naturally resistant to many clinically approved antibiotic families. Oxazolidinone antibiotics are active against many Gram-positive bacteria, but are inactive against P. aeruginosa. Increasing the uptake of oxazolidinones through the bacterial envelope could lead to an increased antibiotic effect. Pyochelin is a siderophore of P. aeruginosa which delivers external iron to the bacterial cytoplasm and is a potential vector for the development of Trojan Horse oxazolidinone conjugates. Novel pyochelin-oxazolidinone conjugates were synthesized using an unexpectedly regioselective peptide coupling between an amine functionalized pyochelin and oxazolidinones functionalized with a terminal carboxylate.     

Ferric iron transport system of Pseudomonas aeruginosa PAO1 that functions as the uptake pathway of a novel catechol-substituted cephalosporin,S-9096

A novel catechol-substituted cephalosporin, S-9096, showed potent antibacterial activity against Pseudomonas aeruginosa under both iron-deficient and aerobic conditions. S-9096 and ferric iron formed a chelate complex at the molar ratio of 3 to 1, which could be incorporated into P. aeruginosa cells grown under such conditions. Incorporation decreased when the cells were grown under either iron-sufficient or anaerobic conditions, with a concomitant disappearance of iron-regulated outer membrane proteins that were considered to function as receptors for ferric siderophores. These results indicated that the ferric chelate of S-9096 was incorporated into P. aeruginosa cells via a ferric iron transport pathway, which caused the high antibacterial potency of S-9096. All of the S-9096-resistant mutants that were able to grow even under iron-deficient conditions lacked an iron-regulated outer membrane protein having an apparent molecular mass of 66 kDa, suggesting the role of this protein as a receptor for the ferric chelate of S-9096. Correspondence to: Y. Yamano     

A cytochrome b561 with ferric reductase activity from the parasitic blood fluke, Schistosoma japonicum

Background

Iron has an integral role in numerous cellular reactions and is required by virtually all organisms. In physiological conditions, iron is abundant in a largely insoluble ferric state. Ferric reductases are an essential component of iron uptake by cells, reducing iron to the soluble ferrous form. Cytochromes b561 (cyts-b561) are a family of ascorbate reducing transmembrane proteins found in most eukaryotic cells. The identification of the ferric reductase duodenal cytochrome b (dcytb) and recent observations that other cyts-b561 may be involved in iron metabolism have opened novel perspectives for elucidating their physiological function.

Methodology/Principal Findings

Here we have identified a new member of the cytochrome b561 (Sjcytb561) family in the pathogenic blood fluke Schistosoma japonicum that localises to the outer surface of this parasitic trematode. Heterologous expression of recombinant Sjcyt-b561 in a Saccharomyces cerevisiae mutant strain that lacks plasma membrane ferrireductase activity demonstrated that the molecule could rescue ferric reductase activity in the yeast.

Significance/Conclusions

This finding of a new member of the cytochrome b561 family further supports the notion that a ferric reductase function is likely for other members of this protein family. Additionally, the localisation of Sjcytb561 in the surface epithelium of these blood-dwelling schistosomes contributes further to our knowledge concerning nutrient acquisition in these parasites and may provide novel targets for therapeutic intervention.     

A computational model of antibiotic-resistance mechanisms in methicillin-resistant Staphylococcus aureus (MRSA)

An agent-based model of bacteria-antibiotic interactions has been developed that incorporates the antibiotic-resistance mechanisms of Methicillin-Resistant Staphylococcus aureus (MRSA). The model, called the Micro-Gen Bacterial Simulator, uses information about the cell biology of bacteria to produce global information about population growth in different environmental conditions. It facilitates a detailed systems-level investigation of the dynamics involved in bacteria-antibiotic interactions and a means to relate this information to traditional high-level properties such as the Minimum Inhibitory Concentration (MIC) of an antibiotic. The two main resistance strategies against β-lactam antibiotics employed by MRSA were incorporated into the model: β-lactamase enzymes, which hydrolytically cleave antibiotic molecules, and penicillin-binding proteins (PBP2a) with reduced binding affinities for antibiotics. Initial tests with three common antibiotics (penicillin, ampicillin and cephalothin) indicate that the model can be used to generate quantitatively accurate predictions of MICs for antibiotics against different strains of MRSA from basic cellular and biochemical information. Furthermore, by varying key parameters in the model, the relative impact of different kinetic parameters associated with the two resistance mechanisms to β-lactam antibiotics on cell survival in the presence of antibiotics was investigated.     

Bacterial defenses against a natural antibiotic promote collateral resilience to clinical antibiotics

Bacterial opportunistic human pathogens frequently exhibit intrinsic antibiotic tolerance and resistance, resulting in infections that can be nearly impossible to eradicate. We asked whether this recalcitrance could be driven by these organisms’ evolutionary history as environmental microbes that engage in chemical warfare. Using Pseudomonas aeruginosa as a model, we demonstrate that the self-produced antibiotic pyocyanin (PYO) activates defenses that confer collateral tolerance specifically to structurally similar synthetic clinical antibiotics. Non-PYO-producing opportunistic pathogens, such as members of the Burkholderia cepacia complex, likewise display elevated antibiotic tolerance when cocultured with PYO-producing strains. Furthermore, by widening the population bottleneck that occurs during antibiotic selection and promoting the establishment of a more diverse range of mutant lineages, PYO increases apparent rates of mutation to antibiotic resistance to a degree that can rival clinically relevant hypermutator strains. Together, these results reveal an overlooked mechanism by which opportunistic pathogens that produce natural toxins can dramatically modulate the efficacy of clinical antibiotics and the evolution of antibiotic resistance, both for themselves and other members of clinically relevant polymicrobial communities.

This study shows that pyocyanin, a toxin secreted by the opportunistic pathogen Pseudomonas aeruginosa, induces defense responses that decrease the efficacy of structurally-similar clinical antibiotics and accelerate the evolution of antibiotic resistance, both in the producer and in other members of clinically-relevant polymicrobial communities.     

IutB participates in the ferric-vulnibactin utilization system in <Emphasis Type="Italic">Vibrio vulnificus</Emphasis> M2799

Vibrio vulnificus, an opportunistic pathogen that causes a serious, often fatal, infection in humans, requires iron for its growth. This bacterium utilizes iron from the environment via the vulnibactin-mediated iron uptake system. The mechanisms of vulnibactin biosynthesis, vulnibactin export, and ferric-vulnibactin uptake systems have been reported, whereas the ferric-vulnibactin reduction mechanism in the cell remains unclear. The results of our previous study showed that VuuB, a member of the flavin adenine dinucleotide-containing siderophore-interacting protein family, is a ferric-vulnibactin reductase, but there are other reductases that can complement for the defective vuuB. The aim of this study was to identify these proteins that can complement the loss of function of VuuB. We constructed mutants of genes encoding putative reductases in V. vulnificus M2799, and analyzed their growth under low-iron conditions. Complementation analyses confirmed that IutB, which functions as a ferric-aerobactin reductase, participates in ferric-vulnibactin reduction in the absence of VuuB. This is the first genetic evidence that ferric-vulnibactin is reduced by a member of the ferric-siderophore reductase protein family. In the aerobactin-utilization system, IutB plays a major role in ferric-aerobactin reduction in V. vulnificus M2799, and VuuB and DesB can compensate for the defect of IutB. Furthermore, the expression of iutB and desB was found to be regulated by iron and a ferric uptake regulator.     

The MAR1 transporter is an opportunistic entry point for antibiotics

The vast quantities of antibiotics used in modern agriculture contaminate the environment and threaten human health. Recent studies have shown that crop plants grown in soil fertilized with manure from antibiotic-treated animals can accumulate antibiotic within the plant body, thus making them an additional antibiotic exposure route for consumers. Until recently, mechanisms of antibiotic entry and subcellular partitioning within plant cells were virtually unknown. We have uncovered and characterized a transporter gene in Arabidopsis thaliana, MAR1, which appears to control antibiotic entry into the chloroplast. Antibiotic resistance via MAR1 is specific to the aminoglycoside class, and is conferred by loss-of-function mutations, which is rather unusual, since most transporter-based antibiotic resistance is conferred by overexpression or gain-of-function mutations in efflux pumps with poor substrate specificity. Since MAR1 overexpression lines exhibit various iron starvation phenotypes, we propose that MAR1 transports an iron chelation molecule that is mimicked specifically by aminoglycoside antibiotics, and this facilitates their entry into the chloroplast. Knowledge about MAR1 enhances our understanding of how antibiotics might enter the plant cell, which may aid in the production of crop plants that are incapable of antibiotic accumulation, as well as further the development of new plant-based antibiotic resistance markers.Key words: antibiotic, contamination, transport, import, chloroplast, membrane, iron, chelation, nicotianamine     

Iron metabolism in the social amoeba Dictyostelium discoideum: A role for ferric chelate reductases

Iron is the most abundant transition metal in all living organisms and is essential for several cellular activities, including respiration, oxygen transport, energy production and regulation of gene expression. Iron starvation is used by professional phagocytes, from Dictyostelium to macrophages, as a form of defense mechanism against intracellular pathogens. Previously, we showed that Dictyostelium cells express the proton-driven iron transporter Nramp1 (Natural Resistance-Associated Macrophage Protein 1) and the homolog NrampB (Nramp2) in membranes of macropinosomes and phagosomes or of the contractile vacuole network, respectively. The Nramp-driven transport of iron across membranes is selective for ferrous ions. Since iron is mostly present as ferric ions in growth media and in engulfed bacteria, we have looked for proteins with ferric reductase activity. The Dictyostelium genome does not encode for classical STEAP (Six-Transmembrane Epithelial Antigen of Prostate) ferric reductases, but harbors three genes encoding putative ferric chelate reductase belonging to the Cytochrome b561 family containing a N terminus DOMON domain (DOpamine β-MONooxygenase N-terminal domain). We have cloned the three genes, naming them fr1A, fr1B and fr1C. fr1A and fr1B are mainly expressed in the vegetative stage while fr1C is highly expressed in the post aggregative stage. All three reductases are localized in the endoplasmic reticulum, but Fr1A is also found in endolysosomal vesicles, in the Golgi and, to a much lower degree, in the plasma membrane, whereas Fr1C is homogeneously distributed in the plasma membrane and in macropinosomal and phagosomal membranes. To gain insight in the function of the three genes we generated KO mutants, but gene disruption was successful only for two of them (fr1A and fr1C), being very likely lethal for fr1B. fr1A- shows a slight delay in the aggregation stage of development, while fr1C- gives rise to large multi-tipped streams during aggregation and displays a strong delay in fruiting body formation. The two single mutants display altered cell growth under conditions of ferric ions overloading and, in the ability to reduce Fe³⁺, confirming a role of these putative ferric reductases in iron reduction and transport from endo-lysosomal vesicles to the cytosol.