High-affinity Iron Transport System Research Articles

Siderophore-Iron Uptake in Saccharomyces cerevisiae: IDENTIFICATION OF FERRICHROME AND FUSARININE TRANSPORTERS

A family of four putative transporters (Arn1p-4p) in Saccharomyces cerevisiae is expressed under conditions of iron deprivation and is regulated by Aft1p, the major iron-dependent transcription factor in yeast. One of these, Arn3p/Sit1p, facilitates the uptake of ferrioxamine B, a siderophore of the hydroxamate class. Here we report that ARN family members facilitated the uptake of iron from the trihydroxamate siderophores ferrichrome, ferrichrome A, and triacetylfusarinine C. Uptake of siderophore-bound iron was dependent on either the high-affinity ferrous iron transport system or the ARN family of transporters. The specificity of each siderophore for individual transporters was determined. Uptake of ferrichrome and ferrichrome A was facilitated by both Arn1p and Arn3p. Uptake of triacetylfusarinine C was facilitated by Arn2p, although small amounts of uptake also occurred through Arn1p and Arn3p. In contrast to the trihydroxamates, uptake of iron from the dihydroxamate rhodotorulic acid occurred only via the high-affinity ferrous iron system. Epitope-tagged Arn1p was expressed in intracellular vesicles in a pattern that was indistinguishable from that of Arn3p, whereas Ftr1p, a component of the high-affinity ferrous system, was expressed on the plasma membrane. These data indicate that S. cerevisiae maintains two systems of siderophore uptake, only one of which is located on the plasma membrane.

CCC1 Suppresses Mitochondrial Damage in the Yeast Model of Friedreich's Ataxia by Limiting Mitochondrial Iron Accumulation

Deletion of YFH1 in Saccharomyces cerevisiae leads to a loss of respiratory competence due to excessive mitochondrial iron accumulation. A suppressor screen identified a gene, CCC1, that maintained respiratory function in a Deltayfh1 yeast strain regardless of extracellular iron concentration. CCC1 expression prevented excessive mitochondrial iron accumulation by limiting mitochondrial iron uptake rather than by increasing mitochondrial iron egress. Expression of CCC1 did not result in sequestration of iron in membranous compartments or cellular iron export. CCC1 expression in wild type cells resulted in increased expression of the high affinity iron transport system composed of FET3 and FTR1, suggesting that intracellular iron is not sensed by the iron-dependent transcription factor Aft1p. Introduction of AFT1(up), a constitutive allele of the iron transcription factor, AFT1, that also leads to increased high affinity iron transport did not prevent Deltayfh1 cells from becoming respiratory-incompetent. Although the mechanism by which CCC1 expression affects cytosolic iron is not known, the data suggest that excessive mitochondrial iron accumulation only occurs when cytosolic free iron levels are high.

Expression of the ferrioxamine receptor gene of Erwinia amylovora CFBP 1430 during pathogenesis.

Mutants of Erwinia amylovora CFBP 1430 lacking a functional high-affinity iron transport system mediated by desferrioxamine are impaired in their ability to initiate fire blight symptoms (A. Dellagi, M.-N. Brisset, J.-P. Paulin, and D. Expert. Mol. Plant-Microbe Interact. 11:734-742, 1998). In this study, a chromosomal transcriptional lacZ fusion was used to analyze the expression in planta of the E. amylovora ferrioxamine receptor gene foxR. LacZ activity produced by the strain harboring the fusion was highly induced in iron-restricted conditions and in inoculated apple leaf tissues. Microscopic observation revealed differential expression of this gene in relation to the localization and density of bacterial cells within the diseased tissue. Thus, the ability of bacterial cells to express their iron transport system in accordance with environmental conditions is likely important for disease evolution.

Iron regulation and pathogenicity in Erwinia chrysanthemi 3937: role of the Fur repressor protein.

Low iron availability is a triggering signal for coordinated expression of the genes encoding pectate lyases PelB, PelC, PelD, and PelE, and chrysobactin iron transport functions, which are two main determinants of phytopathogenicity of the Erwinia chrysanthemi strain 3937. The possible implication of the ferric uptake regulation (Fur) protein in this process was investigated. The E. chrysanthemi fur gene was cloned by functional complementation of an Escherichia coli fur mutant and sequenced. The 444-bp open reading frame identified was found to code for a protein highly similar to the E. coli Fur regulator. An E. chrysanthemi fur null mutant was constructed by reverse genetics. This mutant showed altered growth capacity and reduced pathogenicity on African violets. In a fur background, transcriptional lacZ fusions to genes belonging to the E. chrysanthemi high affinity iron transport systems were constitutively expressed. Transcription of the pelA, pelD, and pelE genes was analyzed, using fusions to the uidA reporter gene. Iron availability and a fur mutation did not influence the expression of pelA. In the presence of iron, pelD and pelE transcription levels were higher in the fur mutant than in the parental strain. Furthermore, iron deficiency stimulated the expression of both fusions in the fur mutant. These findings indicate that, in E. chrysanthemi 3937, (i) Fur negatively controls iron transport and genes encoding PelD and PelE, and (ii) additional factor(s) mediate iron regulation of the pel genes.

Chloride is an allosteric effector of copper assembly for the yeast multicopper oxidase Fet3p: an unexpected role for intracellular chloride channels.

GEF1 is a gene in Saccharomyces cerevisiae, which encodes a putative voltage-regulated chloride channel. gef1 mutants have a defect in the high-affinity iron transport system, which relies on the cell surface multicopper oxidase Fet3p. The defect is due to an inability to transfer Cu+ to apoFet3p within the secretory apparatus. We demonstrate that the insertion of Cu into apoFet3p is dependent on the presence of Cl-. Cu-loading of apoFet3p is favored at acidic pH, but in the absence of Cl- there is very little Cu-loading at any pH. Cl- has a positive allosteric effect on Cu-loading of apoFet3p. Kinetic studies suggest that Cl- may also bind to Fet3p and that Cu+ has an allosteric effect on the binding of Cl- to the enzyme. Thus, Cl- may be required for the metal loading of proteins within the secretory apparatus. These results may have implications in mammalian physiology, as mutations in human intracellular chloride channels result in disease.

Defects in the Yeast High Affinity Iron Transport System Result in Increased Metal Sensitivity because of the Increased Expression of Transporters with a Broad Transition Metal Specificity

Yeast with defects in vacuolar pH show increased sensitivity to high concentrations of transition metals. This sensitivity has been presumed to result from defective metal storage. We demonstrate that mutations that result in a defective high affinity iron transport system, such as a deletion in the surface ferroxidase FET3, also result in increased metal sensitivity independent of vacuolar function. Multiple copies of transition metal transporter resistance genes, such as COT1 or ZRC1, do not reduce the metal sensitivity of fet3 mutations. Increased metal sensitivity is because of an increased cellular accumulation of transition metals resulting from the increased activity of low affinity iron transporters, such as FET4, that mediates the transport of other transition metals. In cells lacking a high affinity iron transport system, the increased transition metal uptake can be prevented by increased extracellular iron. These results suggest that vacuolar function may not be required for transition metal sequestration.

Purification and Characterization of Fet3 Protein, a Yeast Homologue of Ceruloplasmin

The FET3 gene product of Saccharomyces cerevisiae is an essential component of the high affinity iron transport system. Based on FET3 sequence homology to the multicopper oxidase family and iron oxidation studies in spheroplasts (De Silva, D. M., Askwith, C. C., Eide, D., and Kaplan, J. (1995) J. Biol. Chem. 270, 1098-1101), it was hypothesized that the Fet3 protein (Fet3p) was a cell surface ferroxidase. To further characterize the protein, we have isolated Fet3p from yeast membranes and purified the protein to apparent homogeneity. Consistent with its localization at the plasma membrane, Fet3p is a glycosylated protein. SDS-polyacrylamide gel electrophoresis analysis showed that the protein was present in two differentially glycosylated forms of approximately 120 and 100 kDa. Purified Fet3p is a copper-containing protein that is able to catalyze the oxidation of a variety of organic compounds in addition to ferrous iron. Azide and metal chelators strongly inhibited enzyme activity. Iron appeared to be the best substrate for the enzyme, and the apparent Km for ferrous oxidation was 2 microM. Interestingly, Fet3p was able to effectively catalyze the incorporation of iron onto apotransferrin. We conclude that Fet3p is a ferro-O2-oxidoreductase in yeast, homologous to the human plasma protein ceruloplasmin.

Iron acquisition during growth in an iron-deficient medium by Rhizobium sp. isolated from Cicer arietinum

A catechol-type siderophore was produced extracellularly by Rhizobium sp. strain BICC 651 isolated from Cicer arietinum during growth in iron-deficient medium. Production of the siderophore was fully repressed in the presence of 50 μM Fe3+. The siderophore was purified and characterized as containing 2,3-dihydroxybenzoic acid (DHBA) as the core compound and threonine as its conjugate. The siderophore was able to reverse growth inhibition of the strain induced by ethylenediamine-di(o-hydroxyphenyl-acetic acid) (EDDA). A high-affinity iron-transport system capable of transporting 59Fe-siderophore complex was also induced in Rhizobium BICC 651 grown under iron deficiency. Two protein bands of molecular masses 76 and 82 kDa were also inductively synthesized in the outer membrane of the cells. A partially purified ferrireductase enzyme of Rhizobium BICC 651 catalysed reductive release of iron from the ferric chelate of DHBA. The enzyme had a K m of 0.3 mM for ferri-DHBA, was constitutive in nature, and was present in the cytosolic fraction during growth under both iron-deficient and iron-sufficient conditions. The enzyme occurred as two isoenzymes with R F values of 0.48 and 0.51, respectively, in a nondenaturing polyacrylamide gel.

Extent of high-affinity iron transport systems in field isolates of rhizobia

A Uruguayan rhizobia collection (67 isolates) obtained from nodules of Medicago sativa, Melilotus albus, Medicago polymorpha, Trifolium subterraneum, Trifolium repens, Trifolium vesiculosum, Lotus corniculatus, Lotus subbiflorus, Lotus pedunculatus, Ornithopus sp. and Adesmia sp. has been examined to assess the occurrence of high affinity iron uptake systems. CAS (Chrome-azurol S)-assay results suggested that most of the free-living form of these microsymbionts may produce siderophores. The highest siderophore production was observed among Medicago and Trifolium microsymbionts whereas no siderophore expression or moderate positive results were found among Lotus microsymbionts; suggesting that microsymbionts of legumes growing on neutral or alkaline soils may express in vitro enhanced siderophore production. Electrophoretic patterns of outer-membrane protein enriched fractions revealed that iron-limited microsymbionts of Medicago sativa, Lotus corniculatus, Lotus subbiflorus, Trifolium repens, Trifolium subterraneum and Ornithopus sp. produced high molecular weight proteins (ranging from 64 to 94 kDa) compared to cells grown in iron-sufficient media.

The Organization of Intercistronic Regions of the Aerobactin Operon of pCoIV-K30 may Account for the Differential Expression of the iucABCD iutA Genes

The complete nucleotide sequence of the 8·3 kilobase operon of the enterobacterial virulence plasmid pCoIV-K30, which encodes a high-affinity iron transport system mediated by the hydroxamate siderophore aerobactin, has been determined. The region includes five open reading frames which correspond to the genes iucA, iucB, iucC and iucD, encoding the enzymes of the biosynthetic pathway for aerobactin, and iutA for the outer membrane receptor of ferri-aerobactin complexes. The sequences of the iucABCD genes are tightly coupled without any intervening non-coding sequence. The predicted secondary mRNA structures at the gene junctions within the iucABCD cluster, along with their codon usage, may account for the differential expression of each of the protein products, as observed in vivo with minicells. The genes iucA and iucC, which determine the two subunits of the aerobactin synthetase complex, showed a considerable homology within three stretches of their amino acid sequence. A potential operator sequence ( iron box) for the binding of the iron(II)-responsive Fur repressor protein was found within the iucA coding region, suggesting that the operon is subjected to an additional level of transcriptional repression by iron(II).

Characterization of a high-affinity iron transport system in Acinetobacter baumannii.

Analysis of a clinical isolate of Acinetobacter baumannii showed that this bacterium was able to grow under iron-limiting conditions, using chemically defined growth media containing different iron chelators such as human transferrin, ethylenediaminedi-(o-hydroxyphenyl)acetic acid, nitrilotriacetic acid, and 2,2'-bipyridyl. This iron uptake-proficient phenotype was due to the synthesis and secretion of a catechol-type siderophore compound. Utilization bioassays using the Salmonella typhimurium iron uptake mutants enb-1 and enb-7 proved that this siderophore is different from enterobactin. This catechol siderophore was partially purified from culture supernatants by adsorption chromatography using an XAD-7 resin. The purified component exhibited a chromatographic behavior and a UV-visible light absorption spectrum different from those of 2,3-dihydroxybenzoic acid and other bacterial catechol siderophores. Furthermore, the siderophore activity of this extracellular catechol was confirmed by its ability to stimulate energy-dependent uptake of 55Fe(III) as well as to promote the growth of A. baumannii bacterial cells under iron-deficient conditions imposed by 60 microM human transferrin. Polyacrylamide gel electrophoresis analysis showed the presence of iron-regulated proteins in both inner and outer membranes of this clinical isolate of A. baumannii. Some of these membrane proteins may be involved in the recognition and internalization of the iron-siderophore complexes.

Negative transcriptional control of iron transport in Erwinia chrysanthemi involves an iron-responsive two-factor system.

Systemic virulence of the phytopathogen Erwinia chrysanthemi 3937 requires a functional iron assimilation system which, in this enterobacterium, is mediated by the siderophore chrysobactin and the outer membrane transport protein Fct. We investigated the regulation of this system by iron. No direct similarity with the Escherichia coli fur gene was found. Insertional mutagenesis allowed isolation of a regulatory mutant which expressed chrysobactin and two other high-affinity iron transport systems previously characterized in strain 3937, regardless of the iron level. RNA/DNA hybridization analysis established that regulation of chrysobactin by iron occurs at the transcriptional level. From a wild-type gene library, a recombinant cosmid able to restore normal regulation in the mutant strain was isolated. By generating a series of subclones and mini-Mulac insertions, we identified a regulatory locus (cbr) extending beyond c. 2.5kb which encodes two polypeptides, CbrA and CbrB, with molecular weights of 34,000 and 55,000 respectively. Functional analysis of the locus suggests that the cognate genes cbrA and cbrB are clustered within an operon. Their expression was studied through chromosomal lac gene fusions, in the presence of plasmid-borne wild-type constructions, under high- and low-iron conditions. In summary, the data show that in the presence of iron, cbr negatively regulates the chrysobactin biosynthetic and transport genes, while under conditions of depletion, cbr is subject to negative autogeneous regulation.

Mechanisms involved in the pathogenesis of Yersinia infections.

Yersinia enterocolitica and Yersinia pseudotuberculosis are food-borne enterobacterial pathogens which may initiate rheumatoid diseases. By molecular genetic analysis of the pathogenicity of these species virulence gene loci could be identified on the chromosome and on a plasmid. Plasmid-encoded proteins mediate cell adherence, phagocytosis resistance, survival in serum, cytotoxicity, and collagen binding. Y. enterocolitica of serotype 0:8 is mouse-lethal and arthritogenic for Lewis rats. Mouse lethality is closely associated with the expression of a chromosome-encoded high-affinity iron transport system which enables the pathogen to acquire iron for growth in iron-deficient environments. The antibody response to virulence-associated antigens of arthritis-susceptible Lewis rats differed from that of arthritis-resistant Fisher rats: Lewis rats respond strongly to the collagen-binding protein Yop1 and weakly to the iron-transport receptor protein FyuA, whereas the reverse is found with Fisher rats. This specific antibody response of Lewis rats is suggested to be important for induction of arthritis.

Aerobactin production as a virulence factor: A reevaluation

Iron starvation is one of the major barriers that virulent bacteria must overcome in order to proliferate in the host. Virtually all microorganisms possess high affinity iron (III) transport systems mediated by low molecular weight iron specific chelators called siderophores, the synthesis of which is activated under iron-limiting conditions. Siderophore aerobactin is frequently produced by enterobacteria which cause various types of infections in humans and animals. The status of aerobactin production as a virulence factor is evaluated both from data derived from experimental infection systems and the actual presence of this siderophore in clinical isolates. Aerobactin appears to be an important contributor to extracellular pathogenesis (mostly, that of Escherichia coli strains causing septicaemia and urinary tract infections) and to the extracellular stages of growth of intracellular pathogens like Shigella. When invasive bacteria actually enter target cells, acquisition of iron seems to occur independently of siderophore production. The feasibility of an antimicrobial therapy aimed at interfering with siderophore functioning is discussed.

IS1-mediated mobility of the aerobactin system of pColV-K30 in Escherichia coli.

Genes determining the high affinity iron transport system mediated by the siderophore aerobactin are flanked in the enterobacterial plasmid pColV-K30 by inverted repeats of IS1 sequences, suggesting that the aerobactin genes are part of a transposon. To study this possibility, the entire region between the two IS1 sequences was cloned as an 18 kb HindIII-BamHI restriction fragment in pUC8 giving plasmid pMO1. A number of derivatives of pMO1, in which aerobactin genes were tagged with a kanamycin resistance gene, were prepared in order to assess the ability of both IS1s to promote the formation of cointegrates with pCJ105, an F derivative devoid of insertion sequences. Mating-out assays indicated that both flanking IS1s were active in cointegrate formation at detectable frequencies. In some cases, the cointegrates could be resolved, the final result being a transposition-like event for the entire aerobactin system.

Anescherichia colibioassay of individual siderophores in soil

Abstract A bioassay system using mutant strains of Escherichia coli K12 was developed which can detect four different types of siderophores. These types are: ferrichrome and its analogs; enterochelin; coprogen, rhodotorulic acid, and ferrioxamines A, B, D1, and G; and a group of unidentified chelators which forms a part of E. coli's high affinity iron transport system. The amount of the four siderophore types in concentrated water extracts of bulk and rhizosphere soil from a field sample was estimated using this bioassay.

Siderophore production by [formula omitted

This study was initiated to determine the mechanism of iron-uptake in Salmonella typhi . When stressed for iron, microorganisms produce siderophores to obtain the necessary nutrient. Generally two types of siderophores exist: the phenolate-type predominantly produced by bacteria and the hydroxamate-type commonly secreted by fungi. Results of this investigation showed that S. typhi produced siderophores of the phenolate-type since culture supernatant of the organism grown under iron-deprivation supported the growth of the phenolate-dependent auxotroph. The culture supernatant when extracted for phenolate siderophores, also supported the growth of the phenolate auxotroph but not the hydroxamate auxotroph. Production of phenolate-type siderophores were further confirmed using biochemical assays. These results showed that S. typhi utilized the high-affinity iron transport system to obtain the necessary iron.

Iron and virulence in the family Enterobacteriaceae.

The ability of bacterial pathogens to acquire iron in the host is an essential component of the disease process. Pathogenic Enterobacteriaceae spp. may either scavenge host iron sources such as heme or induce high-affinity iron-transport systems to remove iron from host proteins. The ease with which iron is acquired from the host will be at least partially determined by the iron status of the host at the time of infection. In response to infection, mammalian hosts reduce serum iron levels and withhold iron from the invading microorganisms. Thus the competition for iron is an active process which influences the outcome of a host-bacterial interaction.

Ferric uptake regulation protein acts as a repressor, employing iron(II) as a cofactor to bind the operator of an iron transport operon in Escherichia coli

The Fur (ferric uptake regulation) protein is a negative regulator of the aerobactin operon and of several other siderophore-mediated, high-affinity iron transport systems in Escherichia coli. The purified Fur protein and a plasmid containing a lacZ fusion to the aerobactin operon were used in conjunction with an in vitro coupled transcription/translation system to demonstrate that the Fur protein requires Fe(II) or certain other divalent metals as a cofactor to negatively regulate expression of the aerobactin operon. In a second set of experiments, using a restriction site protection assay, Fur was shown to bind to and block the aerobactin promoter in a metal-dependent fashion. It is concluded that Fur acts as a classical negative repressor that, under in vivo conditions, uses ionic Fe(II) as a corepressor. Our results support the hypothesis [Williams, R.J.P. (1982) FEBS Lett. 140, 3-10] that prokaryotic cells may contain a standing pool of free or loosely bound Fe(II) that is capable of acting in a regulatory capacity.

Iron Transport in Azospirillum brasilense: Role of the Siderophore Spirilobactin

SUMMARY: A catechol-type siderophore was secreted by Azospirillum brasilense in the growth medium when the cells became iron-deficient. The siderophore, which we call spirilobactin, was purified and a partial characterization of its structure by hydrolysis revealed that it contained 2,3-dihydroxybenzoic acid, ornithine and serine in equimolar amounts. A high-affinity iron transport system capable of 59Fe uptake from a 59Fe(III)-spirilobactin complex was also induced in A. brasilense grown under iron deficiency. Kinetic studies on the iron uptake system revealed that it was carrier-mediated, with K m and V max values of 0·23 μm and 0·27 nmol Fe min−1(mg cell protein)−1, respectively. Dependence of iron uptake on an energized membrane, its insensitivity to arsenate and inhibition by protonophores suggest that transport is driven by the proton gradient across the membrane. Iron-deficient Azospirillum lipoferum transported 59Fe from the 59Fe(III)-spirilobactin complex (at a rate 3-fold lower than that of A. brasilense) but A. amazonense failed to show uptake of iron under the same conditions.