Isolation and characterisation of catechol-like siderophore from cowpea Rhizobium RA-1

Cowpea Rhizobium RA-1 produced a catechol-like siderophore. Secondary hydroxamic acids were not detected. Bioassay of the siderophore exhibited a distinct zone of growth of cowpea rhizobia. One litre of culture filtrate gave 6.2 mg of catechol-like siderophore. Glycine and threonine were detected in the siderophore. Maximum production of siderophore was found at 36 h of growth of cowpea Rhizobium RA-1.Abbreviations 2,3-DHBA 2,3-dihydroxy benzoic acid - EDTA ethylenediamine tetraacetic acid     

Trishydroxamates and triscatecholates based on monosaccharides and myo-inositol as artificial siderophores

New trishydroxamates and triscatecholates based on methyl -D-glucopyranoside, methyl -D-galactopyranoside, methyl -D-ribopyranoside and methyl -D-xylopyranoside as well as on 1,3,5-tri-O-benzyl-myo-inositol were synthesized. N-Methylsuccinohydroxamate, N-methylglutarohydroxamate and their O-benzoyl derivatives were used as hydroxamate moieties. 2,3-Dihydroxybenzoyl derivatives and acylated compounds as well as 2,3- and 3,4-dihydroxybenzylidenehydrazino derivatives, partly with spacer groups, were utilized as catecholate components. The siderophore activity of the prepared siderophore analogues was examined by a growth promotion assay with various Gram-negative bacteria and mycobacteria and by the CAS-assay. Some trishydroxamates and triscatecholates showed siderophore activity on Gram-negative bacteria and triscatecholates on mycobacteria. Iron complexes of the trishydroxamates act as siderophores for all types of iron transport mutants. The recognition and uptake specificity of these compounds was studied by E. coli siderophore receptor and iron transport mutants. Structure activity correlations are discussed.     

Isolation and characterization of siderophore from cowpeaRhizobium (peanut isolate)

In an iron-depleted broth culture of cowpeaRhizobium (a peanut isolate), phenolate type of compounds were detected. Chemical characterization showed the presence of 2,3-dihydroxy benzoic acid (DHBA) and 3,4-DHBA in the siderophore extract. Lysine and alanine were identified as conjugated amino acids of the siderophore. Maximum concentration of the siderophore in the culture supernatant was found after 24 h of growth. The compounds in the extracted siderophore induced growth ofRhizobium in a medium containing EDTA. Addition of lysine and alanine in the growth medium (20 mM each) led to a fourfold increase in siderophore production.     

Physiological control of amonabactin biosynthesis inAeromonas hydrophila

Summary Amonabactin is a siderophore fromAeromonas hydrophila which is produced in two biologically active forms composed of the phenolate 2,3-dihydroxybenzoic acid (DHB), lysine, glycine, and either trytophan (amonabactin T) or phenylalanine (amonabactin P). Amonabactin biosynthetic mutants (generated by chemical mutagenesis) that either produced no amonabactin or overproduced the siderophore were isolated and identified on chrome azurol S siderophore detection agar. Amonabactin-negative mutants were of two categories. One type produced no phenolates and used exogenous DHB to synthesize amonabactin (both forms) while the other type excreted DHB but not amonabactin. This suggests an amonabactin biosynthetic pathway composed of two segments, one producing DHB and the other assembling amonabactin from DHB and the amino acids. Overproduction mutants used amonabactin poorly or not at all, indicating that they contained lesions in amonabactin utilization. Adding the analogd-tryptophan to wild-typeA. hydrophila cultures reduced synthesis of both amonabactin T and amonabactin P and lengthened the lag phase in iron restricted medium. The tryptophan and phenylalanine forms of amonabactin may be synthesized by a single assembly pathway that contains a novel enzyme (sensitive tod-tryptophan) which inserts either tryptophan or phenylalanine into amonabactin.     

Structure of vulnibactin,a new polyamine-containing siderophore from Vibrio vulnificus

A new siderophore named vulnibactin has been isolated from low iron cultures of Vibrio vulnificus, a human pathogen. The structure was established as N-[3-(2,3-dihydroxybenzamido)propyl]-1,3-bis[2-(2-hydroxyphenyl)-trans-5-methyl-2-oxazoline-4-carboxamido]propane by a combination of acid hydrolysis, nuclear magnetic resonance spectroscopy and positive fast atom bombardment mass spectrometry. Vulnibactin is characterized as containing one residue of 2,3-dihydroxybenzoic acid as well as two residues of salicylic acid, both of which are involved in the formation of oxazoline rings with l-threonine bound to a norspermidine backbone. In addition, two other compounds with siderophore activity were purified and their structures were also determined. These two compounds provided further support for the structure of vulnibactin.     

Increased synthesis of dihydroxybenzoic acid in the presence of aluminum by Rhizobium MO1

Rhizobizum sp. MO1, a mung bean (Vigna radiata) symbiont, produces a catecholate type of siderophore, 2,3-dihydroxy benzoic acid (DHBA), in iron depleted medium. Addition of aluminum to the medium decreased the growth but increased the production of the siderophore.     

Isolation and partial characterization of catechol-type siderophore fromPseudomonas stutzeri RC 7

Pseudomonas stutzeri RC 7 grown under iron-deficient conditions produced catecholtype siderophore, which was identified to be arginine conjugate of 2,3-dihydroxy-benzoic acid. Hydroxamic acids were not detected. The concentration of siderophore in the culture supernatant was maximal after 24 h of growth. Addition of iron to the medium increased bacterial growth but repressed the production of siderophore.     

Rhizoferrin — a novel siderophore from the fungusRhizopus microsporus var.rhizopodiformis

Summary From a strain ofRhizopus microsporus var.rhizopodiformis a novel siderophore, named rhizoferrin, was isolated by ion-exchange column chromatography, gel filtration and preparative HPLC. Hydrolysis with 6 M HCl and subsequent gas chromatography/mass spectrometry (GUMS) of the esterified/trifluoroacetylated derivatives indicated that citric acid and diaminobutane were the only constituents. From positive fastatom-bombardment (FAB) and ion-spray tandem mass spectrometry, a molecular mass of 436 Da and the assignment of several daughter ion fragments could be obtained, which indicated the presence of two citric acid residues and one diaminobutane residue. NMR studies finally confirmedN ¹,N ⁴-bis(1-oxo-3-hydroxy-3,4-dicarboxybutyl)-diaminobutane as the structure of rhizoferrin. The iron-binding property was demonstrated on chromeazurol S plates and its siderophore activity was confirmed by iron transport measurements in young mycelia ofR. microsporus. While rhizoferrin and also ferrioxamines B and E proved to be effective siderophores, coprogen was a poor siderophore in this fungus.     

Isolation and partial characterization of phenolate siderophore from Rhizobium leguminosarum IARI 102

Abstract Rhizobium leguminosarum IARI 102 produced 2,3-dihydroxy benzoic acid, a type of phenolate siderophore, under iron-starved conditions. Hydroxamic acids were not detected. Maximum production of siderophore was found at 26 h of growth in a chemically defined medium at 28°C with shaking. Threonine was detected as the amino acid conjugate of the siderophore. Addition of Fe³⁺ to the culture medium increased the growth yield significantly, but depressed the production of the iron chelating compound.     

New synthetic catecholate-type siderophores based on amino acids and dipeptides

New analogs of bacterial siderophores with one, two or three catecholate moieties were synthesized using various mono- and diamino acid and dipetide scaffolds, respectively. In addition to 2,3-dihydroxybenzoyl siderophore analogs and their acylated derivatives, 3,4-dihydroxybenzoyl derivatives were prepared. Furthermore, the synthesis of a new triscatecholate serving as an intimate model for enterobactin is reported. Most of the new compounds gave a positive CAS-test and were active as siderophores tested by growth promotion assays with a set of siderophore indicator mutants under iron limitation. Structure-activity-correlations have also been studied.     

Aeromonas hydrophila biofilm,exoprotease, and quorum sensing responses to co-cultivation with diverse foodborne pathogens and food spoilage bacteria on crab surfaces

Abstract

The effects of dual species interactions on biofilm formation by Aeromonas hydrophila in the presence of Pseudomonas aeruginosa, Pseudomonas fluorescens, Pectobacterium carotovorum, Salmonella Typhimurium, and Listeria monocytogenes were examined. High-performance liquid chromatography and liquid-chromatography-mass spectrometry were performed to identify N-acyl homoserine lactone (AHL) molecules secreted by monocultures and dual cultures grown in crab broth. Field emission scanning electron microscopy was performed to observe attachment and biofilm formation. P. aeruginosa and P. fluorescens inhibited biofilm formation by A. hydrophila on the crab surface, without affecting their own biofilm-forming abilities. Dual biofilms of S. Typhimurium, L. monocytogenes, or P. carotovorum did not affect A. hydrophila biofilm formation. Exoprotease, AHL, and AI-2 levels were significantly reduced in dual cultures of P. aeruginosa and P. fluorescens with A. hydrophila, supporting the relationship between quorum sensing and biofilm formation. Dual-species biofilms were studied in their natural environment and in the laboratory.     

Competitive exclusion as a mode of action of a novel Bacillus cereus aquaculture biological agent

Aims: To determine the contribution of potential modes of action of a Bacillus cereus aquaculture biological control agent in inhibition of the fish pathogen, Aeromonas hydrophila. Methods and Results: When B. cereus was tested in plate well inhibition studies, no production of antimicrobial compounds was detected. Bacillus cereus had a high growth rate (0·96 h^?1), whereas Aer. hydrophila concentration decreased by c. 70% in co‐culture experiments. In nutrient limitation studies, B. cereus had a significantly higher growth rate when cultured under glucose (P < 0·05) and iron (P < 0·01) limitation in comparison with Aer. hydrophila. Bacillus cereus glucose (0·30 g l^?1 h^?1) and iron (0·60 mg l^?1 h^?1) uptake rates were also significantly higher (P < 0·01) than the Aer. hydrophila glucose (0·14 g l^?1 h^?1) and iron (0·43 mg l^?1 h^?1) uptake rates. Iron uptake was facilitated by siderophore production shown in time profile studies where relative siderophore production was c. 60% through the late exponential and sporulation phases. Conclusions: Competitive exclusion by higher growth rate, competition for organic carbon and iron, facilitated by siderophore production, could be identified as mechanisms of pathogen growth inhibition by B. cereus. Significance and Impact of the Study: This study is the first elucidation of the mechanism of action of our novel B. cereus biological agent in growth attenuation of pathogenic Aer. hydrophila. This study enhances the application knowledge and attractiveness for adoption of B. cereus NRRL 100132 for exploitation in aquaculture.     

Plasma membrane ferric reductase activity of iron-limited algal cells is inhibited by ferric chelators

Iron-limited cells of the green alga Chlorella kesslerii use a reductive mechanism to acquire Fe(III) from the extracellular environment, in which a plasma membrane ferric reductase reduces Fe(III)-chelates to Fe(II), which is subsequently taken up by the cell. Previous work has demonstrated that synthetic chelators both support ferric reductase activity (when supplied as Fe(III)-chelates) and inhibit ferric reductase. In the present set of experiments we extend these observations to naturally-occurring chelators and their analogues (desferrioxamine B mesylate, schizokinen, two forms of dihydroxybenzoic acid) and also two formulations of the commonly-used herbicide N-(phoshonomethyl)glycine (glyphosate). The ferric forms of the larger siderophores (desferrioxamine B mesylate, schizokinen) and Fe(III)-N-(phoshonomethyl)glycine (as the isopropylamine salt) all supported rapid rates of ferric reductase activity, while the iron-free forms inhibited reductase activity. The smaller siderophores/siderophore precursors, 2,3- and 3,4-dihydroxybenzoic acids, did not support high rates of reductase in the ferric form but did inhibit reductase activity in the iron-free form. Bioassays indicated that Fe(III)-chelates that supported high rates of ferric reductase activity also supported a large stimulation in the growth of iron-limited cells, and that an excess of iron-free chelator decreased the growth rate. With respect to N-(phosphonomethyl)glycine, there were differences between the pure compound (free acid form) and the most common commercial formulation (which also contains isopropylamine) in terms of supporting and inhibiting ferric reductase activity and growth. Overall, these results suggest that photosynthetic organisms that use a reductive strategy for iron acquisition both require, and are potentially simultaneously inhibited by, ferric chelators. Furthermore, these results also may provide an explanation for the frequently contradictory results of N-(phosphonomethyl)glycine application to crops: we suggest that low concentrations of this molecule likely solubilize Fe(III), making it available for plant growth, but that higher (but sub-lethal) concentrations decrease iron acquisition by inhibiting ferric reductase activity.     

Xanthoferrin,the α‐hydroxycarboxylate‐type siderophore of Xanthomonas campestris pv. campestris,is required for optimum virulence and growth inside cabbage

Xanthomonas campestris pv. campestris causes black rot, a serious disease of crucifers. Xanthomonads encode a siderophore biosynthesis and uptake gene cluster xss (Xanthomonas siderophore synthesis) involved in the production of a vibrioferrin‐type siderophore. However, little is known about the role of the siderophore in the iron uptake and virulence of X. campestris pv. campestris. In this study, we show that X. campestris pv. campestris produces an α‐hydroxycarboxylate‐type siderophore (named xanthoferrin), which is required for growth under low‐iron conditions and for optimum virulence. A mutation in the siderophore synthesis xssA gene causes deficiency in siderophore production and growth under low‐iron conditions. In contrast, the siderophore utilization ΔxsuA mutant is able to produce siderophore, but exhibits a defect in the utilization of the siderophore–iron complex. Our radiolabelled iron uptake studies confirm that the ΔxssA and ΔxsuA mutants exhibit defects in ferric iron (Fe³⁺) uptake. The ΔxssA mutant is able to utilize and transport the exogenous xanthoferrin–Fe³⁺ complex; in contrast, the siderophore utilization or uptake mutant ΔxsuA exhibits defects in siderophore uptake. Expression analysis of the xss operon using a chromosomal gusA fusion indicates that the xss operon is expressed during in planta growth and under low‐iron conditions. Furthermore, exogenous iron supplementation in cabbage leaves rescues the in planta growth deficiency of ΔxssA and ΔxsuA mutants. Our study reveals that the siderophore xanthoferrin is an important virulence factor of X. campestris pv. campestris which promotes in planta growth by the sequestration of Fe³⁺.     

Temperature Control of a 3,4-Dihydroxybenzoate (Protocatechuate)-Based Siderophore in <Emphasis Type="Italic">Bacillus anthracis</Emphasis>

Bacillus anthracis Sterne produced a catecholate siderophore named anthrachelin that was based on 3,4-dihydroxybenzoic acid (3,4-DHB, or protocatechuic acid), a catechol moiety previously unreported as a siderophore component. During iron restriction, both anthrachelin and free 3,4-DHB were excreted. Growth at 37°C (as compared with 23°C) decreased excretion of anthrachelin but not its precursor 3,4-DHB, suggesting that anthrachelin assembly is temperature regulated. A plasmidless strain also produced anthrachelin in an iron- and temperature-regulated fashion, indicating that anthrachelin genes are chromosomal. In addition to anthrachelin-mediated iron delivery, B. anthracis also used heme, hemoproteins, iron-transferrin, and certain heterologous siderophores (xenosiderophores) produced by other microorganisms as iron sources. Downregulation of anthrachelin production at the temperature of the mammalian host (which triggers toxin production in this pathogen) may focus the B. anthracis iron acquisition systems to exploit the iron sources prevailing in the infected host.     

Amonabactin-mediated iron acquisition from transferrin and lactoferrin by <Emphasis Type="Italic">Aeromonas hydrophila</Emphasis> : direct measurement of individual microscopic rate constants

 The effectiveness and mechanism of iron acquisition from transferrin or lactoferrin by Aeromonas hydrophila has been analyzed with regard to the pathogenesis of this microbe. The ability of A. hydrophila's siderophore, amonabactin, to remove iron from transferrin was evaluated with in vitro competition experiments. The kinetics of iron removal from the three molecular forms of ferric transferrin (diferric, N- and C-terminal monoferric) were investigated by separating each form by urea gel electrophoresis. The first direct determination of individual microscopic rates of iron removal from diferric transferrin is a result. A. hydrophila 495A2 was cultured in an iron-starved defined medium and the growth monitored. Addition of transferrin or lactoferrin promoted bacterial growth. Growth promotion was independent of the level of transferrin or lactoferrin iron saturation (between 30 and 100%), even when the protein was sequestered inside dialysis tubing. Siderophore production was also increased when transferrin or lactoferrin was enclosed in a dialysis tube. Cell yield and growth rate were identical in experiments where transferrin was present inside or outside the dialysis tube, indicating that binding of transferrin was not essential and that the siderophore plays a major role in iron uptake from transferrin. The rate of iron removal from diferric transferrin shows a hyperbolic dependence on amonabactin concentration. Surprisingly, amonabactin cannot remove iron from the more weakly binding N-terminal site of monoferric transferrin, while it is able to remove iron from the more strongly binding C-terminal site of monoferric transferrin. Iron from both sites is removed from diferric transferrin and it is the N-terminal site (which does not release iron in the monoferric protein) that releases iron more rapidly! It is apparent that there is a significant interaction of the two lobes of the protein with regard to the chelator access. Taken together, these results support an amonabactin-dependent mechanism for iron removal by A. hydrophila from transferrin and lactoferrin. The implications of these findings for an amonabactin-dependent mechanism for iron removal by A. hydrophila from transferrin and lactoferrin are discussed. Received: 8 August 1999 / Accepted: 22 October 1999     

Enantioselective synthesis and antioxidant activity of 3‐(3,4‐dihydroxyphenyl)‐glyceric acid—Basic monomeric moiety of a biologically active polyether from Symphytum asperum and S. caucasicum

The racemic and enantioselective synthesis of a novel glyceric acid derivative, namely, 2,3‐dihydroxy‐3‐(3,4‐dihydroxyphenyl)‐propionic acid as well as the antioxidant activities is described. The virtually pure enantiomers, (+)‐(2R,3S)‐2,3‐dihydroxy‐3‐(3,4‐dihydroxyphenyl)‐propionic acid and (?)‐(2S,3R)‐2,3‐dihydroxy‐3‐(3,4‐dihydroxyphenyl)‐propionic acid were synthesized for the first time via Sharpless asymmetric dihydroxylation of trans‐caffeic acid derivatives using the enantiocomplementary catalysts, (DHQD)₂‐PHAL and (DHQ)₂‐PHAL. The determination of enantiomeric purity of the novel chiral glyceric acid derivatives was performed by high‐performance liquid chromatographic techniques on the stage of their alkylated precursors. The novel glyceric acid derivatives show strong antioxidant activity against hypochlorite and N,N‐diphenyl‐N‐picryl‐hydrazyl free radical. Their antioxidant activity is about 40‐fold higher than that of the corresponding natural polyether and three‐fold higher of trans‐caffeic acid itself. Chirality, 2010. © 2010 Wiley‐Liss, Inc.     

Soluble and membrane-bound ferrisiderophore reductases of Escherichia coli K-12

After uptake of microbial ferrisiderophores, iron is assumed to be released by reduction. Two ferrisiderophore-reductase activities were identified in Escherichia coli K-12. They differed in cellular location, susceptibility to amytal, and competition between oxygen and ferrichrome-iron(III) reduction. The ferrisiderophore reductase associated with the 40,000×g sediment (membrane-bound enzyme) was inhibited by 10 mM amytal in contrast to the ferrisiderophore reductase present in the 100,000×g supernatant (soluble enzyme). Reduction by the membrane-bound enzyme followed sigmoid kinetics, but was biphasic in the case of the soluble enzyme. The soluble reductase could be assigned to a protein consisting of a single polypeptide of M _r 26000. Reduction of iron(III) by the purified enzyme depended on the addition of NADH or NADPH which were equally active reductants. The cofactor FMN and to a lesser degree FAD stimulated the reaction. Substrate specificity of the soluble reductase was low. In addition to the hydroxamate siderophores arthrobactin, schizokinen, fusigen, aerobactin, ferrichrome, ferrioxamine B, coprogen, and ferrichrome A, the iron(III) complexes of synthetic catecholates, dihydroxy benzoic acid, and dicitrate, as well as carrier-free iron(III) were accepted as substrates. Both ferrisiderophore reductases were not controlled by the fur regulatory system and were not suppressed by anaerobic growth.Abbreviations DHB dihydroxybenzoic acid - MECAM 1,3,5-N,N,N-tris-(2,3-dihydroxybenzoyl)-triamino-methylbenzene - MECAMS 2,3-dihydroxy-5-sulfonyl-derivative of MECAM     

基于生物信息学分析从Streptomyces albofaciens JCM 4342中发现2,3-二羟基苯甲酸酯-L-丝氨酸脱水三聚体和二聚体天然产物

[背景] 铁是细菌生长的基本元素,而三价铁在自然水环境中几乎无法溶解。细菌已经进化出产生各种铁载体的能力,以促进铁的吸收。对于链霉菌,其特有的铁载体是去铁胺,同时它们也可以产生其他结构的铁载体,如ceolichelin、白霉素、肠杆菌素（enterobactin）和griseobactin。[目的] 揭示链霉菌中铁载体生物合成基因簇（Biosynthetic Gene Clusters,BGCs）的分布特点和基因簇特征,并探索其所合成铁载体的化合物结构。[方法] 利用生物信息学工具系统地分析308个具有全基因组序列信息的链霉菌中的铁载体生物合成基因簇,并用色谱和波谱方法分离和表征肠杆菌素相关天然产物。[结果] 发现Streptomyces albofaciens JCM 4342和其他少数菌株同时含有一个缺少2,3-二羟基苯甲酸（2,3-DHB）生物合成基因的孤立的肠杆菌素生物合成基因簇和另外一个推测可合成griseobactin的基因簇。从S.albofaciens JCM 4342发酵液中鉴定出4个肠杆菌素衍生的天然产物,包括链状2,3-二羟基苯甲酸酯-l-丝氨酸（2,3-DHBS）的三聚体和二聚体以及它们的脱水产物。[结论] 2个基因簇间存在一种特别的协同生物合成机制。推测是griseobactin基因簇负责合成2,3-DHB,而孤立的肠杆菌素基因簇编码的生物合成酶可夺取该底物,进而完成上述4种肠杆菌素衍生天然产物的生物合成。