Influence of iron depletion on growth and production of catechol siderophores by different Frankia strains

Nine strains of Frankia isolated from six Casuarinaceae (including four Casuarina sp., one Allocasuarina and one Gymnostoma) and one Elaeagnaceae (Hippophae¨ rhamnoides) were screened for growth and production of siderophores in an iron-deficient liquid medium. Siderophore production was detected only in four strains (Cj, G2, CH and G82) using the CAS and Arnow assays. Salicylates formed more than 90% and dihydroxybenzoates formed less than 10% of all catechol-type siderophores produced. Growth of the former strains was less affected by iron deficiency than that of strains Rif, Thr, URU, BR and RT which do not produce siderophores. Optimal siderophore production by strain Cj was noted when iron concentration reached 0.5μm and was completely inhibited at an iron concentration of 10μm. The kinetics of siderophore production by strain Cj showed that siderophore synthesis was detectable during the growth stationary phase. Growth of Cj (a siderophore-producing strain) and of RT (a non-siderophore-producing strain) differed when 2,2-dipyridyl or ethylene di(o-hydroxyphenyl) acetic acid (EDDHA) was added to the iron-deficient growth medium. Frankia strain RT was the most sensitive to the detrimental effect of both iron chelators.     

Influence of iron depletion on growth and production of catechol siderophores by different Frankia strains

Nine strains of Frankia isolated from six Casuarinaceae (including four Casuarina sp., one Allocasuarina and one Gymnostoma) and one Elaeagnaceae (Hippophae¨ rhamnoides) were screened for growth and production of siderophores in an iron-deficient liquid medium. Siderophore production was detected only in four strains (Cj, G2, CH and G82) using the CAS and Arnow assays. Salicylates formed more than 90% and dihydroxybenzoates formed less than 10% of all catechol-type siderophores produced. Growth of the former strains was less affected by iron deficiency than that of strains Rif, Thr, URU, BR and RT which do not produce siderophores. Optimal siderophore production by strain Cj was noted when iron concentration reached 0.5m and was completely inhibited at an iron concentration of 10m. The kinetics of siderophore production by strain Cj showed that siderophore synthesis was detectable during the growth stationary phase. Growth of Cj (a siderophore-producing strain) and of RT (a non-siderophore-producing strain) differed when 2,2-dipyridyl or ethylene di(o-hydroxyphenyl) acetic acid (EDDHA) was added to the iron-deficient growth medium. Frankia strain RT was the most sensitive to the detrimental effect of both iron chelators.     

De novo synthesis of ferrichrome by Fusarium oxysporum f. sp. cubense TR4 in response to iron starvation

Manipulation of iron bioavailability in the banana rhizosphere may suppress Fusarium wilt, caused by Fusarium oxysporum f. sp. cubense (Foc). However, iron starvation induced by application of synthetic iron chelators does not effectively suppress Fusarium wilt. It is unclear whether Foc can subvert iron chelators and thereby evade iron starvation through the synthesis of iron-scavenging secondary metabolites, called siderophores. In vitro studies were conducted using iron-deficient growth medium and medium supplemented with a synthetic iron chelator, 2,2′-dipyridyl, to mimic iron starvation in Foc Tropical Race 4 (Foc TR4). Concentration of extracellular siderophores increased three-fold (p < 0.05) in the absence of iron. Liquid chromatography-mass spectrometry analysis detected the hydroxamate siderophore, ferrichrome, only in the mycelia of iron-starved cultures. Moreover, iron-starved cultures exhibited a reduction in total cellular protein concentration. In contrast, out of the 20 proteinogenic amino acids, only arginine increased (p < 0.05) under iron starvation. Our findings suggest that iron starvation does not cause a remodelling of amino acid metabolism in Foc TR4, except for arginine, which is required for biosynthesis of ornithine, the precursor for siderophore biosynthesis. Collectively, our findings suggest that biosynthesis of siderophores, particularly ferrichrome, could be a counteractive mechanism for Foc TR4 to evade iron starvation.     

Iron-Binding Compounds from Agrobacterium spp.: Biological Control Strain Agrobacterium rhizogenes K84 Produces a Hydroxamate Siderophore

Iron-binding compounds were produced in various amounts in response to iron starvation by a collection of Agrobacterium strains belonging to the species A. tumefaciens, A. rhizogenes, and A. vitis. The crown gall biocontrol agent A. rhizogenes strain K84 produced a hydroxamate iron chelator in large amounts. Production of this compound, and also of a previously described antibiotic-like substance called ALS84, occurred only in cultures of strain K84 grown in iron-deficient medium. Similarly, sensitivity to ALS84 was expressed only when susceptible cells were tested in low-iron media. Five independent Tn5-induced mutants of strain K84 affected in the production of the hydroxamate iron chelator showed a similar reduction in the production of ALS84. One of these mutants, M8-10, was completely deficient in the production of both agents and grew poorly compared to the wild type under iron-limiting conditions. Thus, the hydroxamate compound has siderophore activity. A 9.1-kb fragment of chromosomal DNA containing the Tn5 insertion from this mutant was cloned and marker exchanged into wild-type strain K84. The homogenote lost the ability to produce the hydroxamate siderophore and also ALS84. A cosmid clone was isolated from a genomic library of strain K84 that restored to strain M8-10 the ability to produce of the siderophore and ALS84, as well as growth in iron-deficient medium. This cosmid clone contained the region in which Tn5 was located in the mutant. Sequence analysis showed that the Tn5 insert in this mutant was located in an open reading frame coding for a protein that has similarity to those of the gramicidin S synthetase repeat superfamily. Some such proteins are required for synthesis of hydroxamate siderophores by other bacteria. Southern analysis revealed that the biosynthetic gene from strain K84 is present only in isolates of A. rhizogenes that produce hydroxamate-type compounds under low-iron conditions. Based on physiological and genetic analyses showing a correlation between production of a hydroxamate siderophore and ALS84 by strain K84, we conclude that the two activities share a biosynthetic route and may be the same compound.     

Induction of siderophore activity in Anabaena spp. and its moderation of copper toxicity.

Growth of Anabaena sp. strain 7120 (in the absence of chelators or added iron) was inhibited by the addition of 2.1 to 6.5 microM copper and was abolished by copper concentration of 10 microM or higher. When the copper was chelated to schizokinen (the siderophore produced by this organism in response to iron starvation), the toxic effects were eliminated. Analysis of culture filtrates showed that the cupric schizokinen remains in the medium, thereby lowering the amount of copper taken up by the cells. Although this organism actively transports ferric schizokinen, it apparently does not recognize the cupric complex. Thus, Anabaena sp. is protected from copper toxicity under conditions in which siderophore is being produced. For cells grown in low iron, the accumulation of extracellular schizokinen was observed to parallel cell growth and continue well into stationary phase. The actual iron status of the organism was monitored by using iron uptake velocity as an assay. Cultures grown on 0.1 microM added iron were found to be severely iron limited upon reaching stationary phase, thus explaining the continued production of schizokinen. These data show that the siderophore system in Anabaena spp. has developed primarily as a response to iron starvation and that additional functions such as alleviation of copper toxicity or allelopathic inhibition of other algal species are merely secondary benefits.     

Induction of siderophore activity in Anabaena spp. and its moderation of copper toxicity

Growth of Anabaena sp. strain 7120 (in the absence of chelators or added iron) was inhibited by the addition of 2.1 to 6.5 microM copper and was abolished by copper concentration of 10 microM or higher. When the copper was chelated to schizokinen (the siderophore produced by this organism in response to iron starvation), the toxic effects were eliminated. Analysis of culture filtrates showed that the cupric schizokinen remains in the medium, thereby lowering the amount of copper taken up by the cells. Although this organism actively transports ferric schizokinen, it apparently does not recognize the cupric complex. Thus, Anabaena sp. is protected from copper toxicity under conditions in which siderophore is being produced. For cells grown in low iron, the accumulation of extracellular schizokinen was observed to parallel cell growth and continue well into stationary phase. The actual iron status of the organism was monitored by using iron uptake velocity as an assay. Cultures grown on 0.1 microM added iron were found to be severely iron limited upon reaching stationary phase, thus explaining the continued production of schizokinen. These data show that the siderophore system in Anabaena spp. has developed primarily as a response to iron starvation and that additional functions such as alleviation of copper toxicity or allelopathic inhibition of other algal species are merely secondary benefits.     

Bacillus anthracis requires siderophore biosynthesis for growth in macrophages and mouse virulence

Systemic anthrax infections can be characterized as proceeding in stages, beginning with an early intracellular establishment stage within phagocytes that is followed by extracelluar stages involving massive bacteraemia, sepsis and death. Because most bacteria require iron, and the host limits iron availability through homeostatic mechanisms, we hypothesized that B. anthracis requires a high-affinity mechanism of iron acquisition during its growth stages. Two putative types of siderophore synthesis operons, named Bacillus anthracis catechol, bac (anthrabactin), and anthrax siderophore biosynthesis, asb (anthrachelin), were identified. Directed gene deletions in both anthrabactin and anthrachelin pathways were generated in a B. anthracis (Sterne) 34F2 background resulting in mutations in asbA and bacCEBF. A decrease in siderophore production was observed during iron-depleted growth in both the DeltaasbA and DeltabacCEBF strains, but only the DeltaasbA strain was attenuated for growth under these conditions. In addition, the DeltaasbA strain was severely attenuated both for growth in macrophages (MPhi) and for virulence in mice. In contrast, the DeltabacCEBF strain did not differ phenotypically from the parental strain. These findings support a requirement for anthrachelin but not anthrabactin in iron assimilation during the intracellular stage of anthrax.     

Bifidobacteria strains isolated from stools of iron deficient infants can efficiently sequester iron

Background

Bifidobacteria is one of the major gut commensal groups found in infants. Their colonization is commonly associated with beneficial effects to the host through mechanisms like niche occupation and nutrient competition against pathogenic bacteria. Iron is an essential element necessary for most microorganisms, including bifidobacteria and efficient competition for this micronutrient is linked to proliferation and persistence. For this research we hypothesized that bifidobacteria in the gut of iron deficient infants can efficiently sequester iron. The aim of the present study was to isolate bifidobacteria in fecal samples of iron deficient Kenyan infants and to characterize siderophore production and iron internalization capacity.

Results

Fifty-six bifidobacterial strains were isolated by streaking twenty-eight stool samples from Kenyan infants, in enrichment media. To target strains with high iron sequestration mechanisms, a strong iron chelator 2,2-dipyridyl was supplemented to the agar media. Bifidobacterial isolates were first identified to species level by 16S rRNA sequencing, yielding B. bifidum (19 isolates), B. longum (15), B. breve (11), B. kashiwanohense (7), B. pseudolongum (3) and B. pseudocatenulatum (1). While most isolated bifidobacterial species are commonly encountered in the infantile gut, B. kashiwanohense was not frequently reported in infant feces. Thirty strains from culture collections and 56 isolates were characterized for their siderophore production, tested by the CAS assay. Siderophore activity ranged from 3 to 89% siderophore units, with 35 strains (41%) exhibiting high siderophore activity, and 31 (36%) and 20 (23%) showing intermediate or low activity. The amount of internalized iron of 60 bifidobacteria strains selected for their siderophore activity, was in a broad range from 8 to118 μM Fe. Four strains, B. pseudolongum PV8-2, B. kashiwanohense PV20-2, B. bifidum PV28-2a and B. longum PV5-1 isolated from infant stool samples were selected for both high siderophore activity and iron internalization.

Conclusions

A broad diversity of bifidobacteria were isolated in infant stools using iron limited conditions, with some strains exhibiting high iron sequestration properties. The ability of bifidobacteria to efficiently utilize iron sequestration mechanism such as siderophore production and iron internalization may confer an ecological advantage and be the basis for enhanced competition against enteropathogens.

Electronic supplementary material

The online version of this article (doi:10.1186/s12866-014-0334-z) contains supplementary material, which is available to authorized users.     

Incorporation of l-lysine and 2,2′-dipyridyl in the growth media promotes desferrioxamine E production by an actinobacterium

The study describes the use of the chelating agent 2,2′-dipyridyl in conjunction with lysine to increase the production of the siderophore desferrioxamine E by a previously described actinobacterium 23F. Desferrioxamine E is a type of siderophore known to be produced by Streptomycete species. Lysine is a precursor of the siderophore and its presence in the culture medium is known to promote desferrioxamine E synthesis. The further addition of 2,2′-dipyridyl was found to enhance production of the siderophore in the presence of lysine (5 g l^?1) nearly twofold when incorporated at a concentration of 200 μM. Increasing the concentration of the chelating agent above 200 μM resulted in a decrease in siderophore production. The role of the chelating agent was thought to be in creating iron-limiting conditions in the culture medium and so promoting the induction of the desferrioxamine E biosynthetic pathway. This medium is likely to be a useful tool in the screening for producers of desferrioxamine E.     

Genomics of the 35-kb pvd locus and analysis of novel pvdIJK genes implicated in pyoverdine biosynthesis in Pseudomonas aeruginosa

Novel putative pyoverdine synthetase pvdIJK genes were found upstream of pvdD in the 6.2-Mb chromosome of Pseudomonas aerugilosa strain PAO1. These genes formed a locus implicated in pyoverdine biosynthesis. Sequence analysis showed that the product of these genes shared 43%, 60% and 57% identity with PvdD. PvdIJK are thought to be implicated in synthesis of pyoverdine, a siderophore chelating Fe3+. A pvdI mutant was obtained by gene disruption mutagenesis and confirmed by Southern hybridization. The pvdl mutant produced gave no significant growth on solid media supplemented with the iron chelator 2,2-dipyridyl; while the PvdI- phenotype abolished pyoverdine fluorescence. The role of PvdI in pathogenicity was tested by measuring the in vivo growth of P. aeruginosa wild-type and mutant strains in a chronic lung infection rat model, and by measuring the competitive infectivity index into a neutropenic mice model. The data obtained confirmed the importance of PvdI in virulence and iron uptake.     

Siderophore-mediated iron uptake in different strains of Anabaena sp.

Anabaena sp. strain 6411, which produces the dihydroxamate siderophore schizokinen to facilitate iron uptake, is also capable of using the related siderophore aerobactin. The two siderophores compete for the same iron transport system, but there is a markedly higher affinity for ferric schizokinen than for ferric aerobactin. The trihydroxamate siderophore ferrioxamine B is far less effective as an iron donor in this organism. Anabaena sp. strain 7120 appears to be closely related to strain 6411. It synthesizes schizokinen as its major siderophore and shows rates of iron uptake from ferric schizokinen, ferric aerobactin, and ferrioxamine B which are similar to those observed with strain 6411. Anabaena cylindrica Lemm. 7122 and 1611, on the other hand, differ from strain 6411. In contrast to schizokinen, the hydroxamate which they produce in response to iron starvation cannot be extracted with water from the organic layer and does not support the growth of the siderophore auxotroph Arthrobacter flavescens JG-9. Strain 7122 can use its endogenous siderophore or schizokinen to promote iron uptake, but at 50-fold-lower rates than are observed with Anabaena sp. strain 6411 or 7120.     

Citrate as a siderophore in Bradyrhizobium japonicum.

Under iron-limiting conditions, many bacteria secrete ferric iron-specific ligands, generically termed siderophores, to aid in the sequestering and transport of iron. One strain of the nitrogen-fixing soybean symbiont Bradyrhizobium japonicum, 61A152, was shown to produce a siderophore when 20 B. japonicum strains were screened with all six chemical assays commonly used to detect such production. Production by strain 61A152 was detected via the chrome azurol S assay, a general test for siderophores which is independent of siderophore structure. The iron-chelating compound was neither a catechol nor a hydroxamate and was ninhydrin negative. It was determined to be citric acid via a combination of thin-layer chromatography and high-voltage paper electrophoresis; this identification was verified by a specific enzymatic assay for citric acid. The inverse correlation which was observed between citric acid release and the iron content of the medium suggested that ferric citrate could serve as an iron source. This was confirmed via growth and transport assays. Exogenously added ferric citrate could be used to overcome iron starvation, and iron-deficient cells actively transported radiolabeled ferric citrate. These results, taken together, indicate a role for ferric citrate in the iron nutrition of this strain, which has been shown to be an efficient nitrogen-fixing strain on a variety of soybean cultivars.     

Molecular cloning and expression of genetic determinants for the iron uptake system mediated by the Vibrio anguillarum plasmid pJM1

Plasmid pJM1 from an invasive strain of Vibrio anguillarum encodes an iron uptake system which mediates the biosynthesis of a siderophore and a membrane receptor for the iron-siderophore complex. This system has been associated with the ability of V. anguillarum to cause hemorrhagic septicemic disease in marine fish. Recombinant derivatives containing essential regions of the pJM1-mediated iron uptake system cloned into cosmid vector pVK102 were introduced into low-virulence iron uptake-deficient V. anguillarum strains by using a trifactor mating procedure with helper plasmid pRK2013. Three recombinant clones, pJHC-T7, pJHC-T11, and pJHC-T2612, possessed genetic determinants for receptor activity. Production of receptor activity was correlated in all three cases with the presence of OM2, an 86-kilodalton outer membrane protein which was induced under iron-limiting conditions. Two of the clones, pJHC-T7 and pJHC-T2612, also coded for the production of siderophore activity, although at a much lower level than the wild type. Strains harboring either of these two clones were still unable to grow under iron-limiting conditions. This inability was overcome only when other indigenous pJM1 derivatives were present in the cells in addition to the recombinant cosmids. This restoration of high siderophore production and ability to grow under iron-limiting conditions was achieved even when the indigenous plasmids possessed lesions in genes involved in siderophore activity or in both siderophore and receptor production. Thus, another function mediated by plasmid pJM1, possibly a transacting factor, may play a role in the regulation of siderophore production. Results of experimental infections demonstrated that restoration of the ability to grow under conditions of iron limitations by introduction of an recombinant clone into one of the low-virulence V. anguillarum strains was correlated with an increase in bacterial pathogenicity.     

Siderophore production in relation to N2 fixation and iron uptake in pigeon pea-Rhizobium symbiosis

Thirty-one bradyrhizobial and rhizobial strains infecting pigeon pea were screened for siderophore production using Chrome Azurol S (CAS) agar plate as well as a CAS assay solution. Of a total of 31 strains only 23 showed siderophore production. Of the 23 siderophore-positive strains, 21 strains showed the production of hydroxamate while 6 strains showed the presence of catechol type of siderophore. A large variation in the quantity of hydroxamate and catechol produced by different rhizobial strains was observed (1.03–3.73 μg hydroxamate N per mg protein; 0.19–3.43 μmol/L of catechol per mg protein). Maximum nodule biomass was produced by strain PP-11 (CC-1020); strain G-14 formed minimum nodule biomass. Nitrogen contents of low, moderate and high siderophore-producing strains were 11.4, 15.4, 20.9 mg per plant, respectively, iron contents were 1445, 1768 and 2003 ppm, respectively. Siderophore production was related to N₂-fixing efficiency.     

Investigations of Salmonella strains from different clinical-epidemiological origin with phenolate and hydroxamate (aerobactin)--siderophore bioassays

By means of phenolate siderophore negative S. typhimurium mutants as indicators, a bioassay for the detection of phenolate production was applied in Salmonella species. Different Salmonella strains have a weak or normal phenolate siderophore production. Host-adapted Salmonella strains show weak, other strains of Salmonella show normal growth zones of the indicator strain. Besides phenolate siderophore production there are defined S. typhimurium strains, exhibiting phage type ut/ut, biochemical type a and some strains of S. wien, S. infantis and S. haifa from nosocomial infection producing hydroxamate siderophore (aerobactin) as a compotent of a second iron uptake system.     

Multiple modes of iron uptake by the filamentous,siderophore‐producing cyanobacterium,Anabaena sp. PCC 7120

Iron is a member of a small group of nutrients that limits aquatic primary production. Mechanisms for utilizing iron have to be efficient and adapted according to the ecological niche. In respect to iron acquisition cyanobacteria, prokaryotic oxygen evolving photosynthetic organisms can be divided into siderophore‐ and non‐siderophore‐producing strains. The results presented in this paper suggest that the situation is far more complex. To understand the bioavailability of different iron substrates and the advantages of various uptake strategies, we examined iron uptake mechanisms in the siderophore‐producing cyanobacterium Anabaena sp. PCC 7120. Comparison of the uptake of iron complexed with exogenous (desferrioxamine B, DFB) or to self‐secreted (schizokinen) siderophores by Anabaena sp. revealed that uptake of the endogenous produced siderophore complexed to iron is more efficient. In addition, Anabaena sp. is able to take up dissolved, ferric iron hydroxide species (Fe′) via a reductive mechanism. Thus, Anabaena sp. exhibits both, siderophore‐ and non‐siderophore‐mediated iron uptake. While assimilation of Fe′ and FeDFB are not induced by iron starvation, FeSchizokinen uptake rates increase with increasing iron starvation. Consequently, we suggest that Fe′ reduction and uptake is advantageous for low‐density cultures, while at higher densities siderophore uptake is preferred.     

Response of the cyanobacterium,Oscillatoria tenuis,to low iron environments: the effect on growth rate and evidence for siderophore production

Cyanobacteria vary in their ability to grow in media contaning low amounts of biologically available iron. Some strains, such as Oscillatoria tenuis, are well adapted to thrive in low-iron environments. We investigated the mechanism of iron scavenging in O. tenuis and found that this cyanobacterium has a siderophore-mediated iron transport system that differs significantly from the traditional hydroxamate-siderophore transport system reported from other cyanobacteria. Unlike other cyanobacteria, this strain produces two types of siderophores, a hydroxamate-type siderophore and a catechol-type siderophore. Production of these two siderophores is expressed at two different iron levels in the medium, suggesting two different iron regulated uptake systems. We compared the production of each siderophore with the growth rate of the culture and found that the production of the catechol siderophore enhances the growth rate of the cyanobacterium, whereas the cells maintain lower than maximal growth rates when only the hydroxamate-type siderophore is being produced.Abbreviation EDDA ethylene diamine di-(o-hydroxyphenylacetic acid)