The interplay between siderophore secretion and coupled iron and copper transport in the heterocyst-forming cyanobacterium Anabaena sp. PCC 7120.

Iron uptake is essential for Gram-negative bacteria including cyanobacteria. In cyanobacteria, however, the iron demand is higher than in proteobacteria due to the function of iron as a cofactor in photosynthesis and nitrogen fixation, but our understanding of iron uptake by cyanobacteria stands behind the knowledge in proteobacteria. Here, two genes involved in this process in the heterocyst-forming cyanobacterium Anabaena sp. PCC 7120 were identified. ORF all4025 encodes SchE, a putative cytoplasmic membrane-localized transporter involved in TolC-dependent siderophore secretion. Inactivation of schE resulted in an enhanced sensitivity to high metal concentrations and decreased secretion of hydroxamate-type siderophores. ORF all4026 encodes a predicted outer membrane-localized TonB-dependent iron transporter, IacT. Inactivation of iacT resulted in decreased sensitivity to elevated iron and copper levels. Expression of iacT from the artificial trc promoter (P(trc)) resulted in sensitization against tested metals. Further analysis showed that iron and copper effects are synergistic because a decreased supply of iron induced a significant decrease of copper levels in the iacT insertion mutant but an increase of those levels in the strain carrying P(trc)-iacT. Our results unravel a link between iron and copper homeostasis in Anabaena sp. PCC 7120.

Salmochelin, the long-overlooked catecholate siderophore of Salmonella.

Salmochelin is a C-glucosylated enterobactin produced by Salmonella species, uropathogenic and avian pathogenic Escherichia coli strains, and certain Klebsiella strains. It was the first glucosylated siderophore described. The glucosylation has been interpreted as a bacterial evasion mechanism against the mammalian catecholate siderophore-binding protein siderocalin (NGAL-lipocalin). The synthesis, excretion, and uptake of salmochelin requires five genes, iroBCDEN, and also the enterobactin biosynthesis and utilization system. Some salmochelin-producing strains also secrete microcins, which possess a C-terminal, linear glucosyl-enterobactin moiety. These microcins recognize the catecholate siderophore receptors IroN, Cir, Fiu, and FepA, and may inhibit the growth of competitors for catecholate siderophores.

Alr0397 is an outer membrane transporter for the siderophore schizokinen in Anabaena sp. strain PCC 7120.

Iron uptake in proteobacteria by TonB-dependent outer membrane transporters represents a well-explored subject. In contrast, the same process has been scarcely investigated in cyanobacteria. The heterocyst-forming cyanobacterium Anabaena sp. strain PCC 7120 is known to secrete the siderophore schizokinen, but its transport system has remained unidentified. Inspection of the genome of strain PCC 7120 shows that only one gene encoding a putative TonB-dependent iron transporter, namely alr0397, is positioned close to genes encoding enzymes involved in the biosynthesis of a hydroxamate siderophore. The expression of alr0397, which encodes an outer membrane protein, was elevated under iron-limited conditions. Inactivation of this gene caused a moderate phenotype of iron starvation in the mutant cells. The characterization of the mutant strain showed that Alr0397 is a TonB-dependent schizokinen transporter (SchT) of the outer membrane and that alr0397 expression and schizokinen production are regulated by the iron homeostasis of the cell.

NagA-dependent uptake of N-acetyl-glucosamine and N-acetyl-chitin oligosaccharides across the outer membrane of Caulobacter crescentus.

Among the 67 predicted TonB-dependent outer membrane transporters of Caulobacter crescentus, NagA was found to be essential for growth on N-acetyl-beta-D-glucosamine (GlcNAc) and larger chitin oligosaccharides. NagA (93 kDa) has a predicted typical domain structure of an outer membrane transport protein: a signal sequence, the TonB box EQVVIT, a hatch domain of 147 residues, and a beta-barrel composed of 22 antiparallel beta-strands linked by large surface loops and very short periplasmic turns. Mutations in tonB1 and exbBD, known to be required for maltose transport via MalA in C. crescentus, and in two additional predicted tonB genes (open reading frames cc2327 and cc3508) did not affect NagA-mediated GlcNAc uptake. nagA is located in a gene cluster that encodes a predicted PTS sugar transport system and two enzymes that convert GlcNAc-6-P to fructose-6-P. Since a nagA insertion mutant did not grow on and transport GlcNAc, diffusion of GlcNAc through unspecific porins in the outer membrane is excluded. Uptake of GlcNAc into tonB and exbBD mutants and reduction but not abolishment of GlcNAc transport by agents which dissipate the electrochemical potential of the cytoplasmic membrane (0.1 mM carbonyl cyanide 3-chlorophenylhydrazone and 1 mM 2,4-dinitrophenol) suggest diffusion of GlcNAc through a permanently open pore of NagA. Growth on (GlcNAc)(3) and (GlcNAc)(5) requires ExbB and ExbD, indicating energy-coupled transport by NagA. We propose that NagA forms a small pore through which GlcNAc specifically diffuses into the periplasm and functions as an energy-coupled transporter for the larger chitin oligosaccharides.

Special conditions allow binding of the siderophore salmochelin to siderocalin (NGAL-lipocalin).

Siderocalin is part of the innate immune system and is secreted by epithelial cells in the early stages of inflammation. This protein binds catecholate siderophores such as enterobactin with high affinity. As a consequence, the iron supply and growth of the siderophore-producing bacteria is disturbed. Recombinant siderocalin isolated from strains of Escherichia coli K-12 contained bound enterobactin. Very low amounts of siderocalin were isolated from another K-12 strain unable to produce enterobactin, which indicated that enterobactin might stabilize the recombinant protein. Siderocalin isolated from E. coli strain Nissle 1917, which produces the glucosylated enterobactin salmochelin, contained a mixture of bound salmochelin (55%) and enterobactin (45%). The growth of an enterobactin-producing E. coli K-12 strain but not of the same strain carrying a plasmid encoding iroBCDEN and therefore able to produce salmochelin was suppressed when siderocalin was added to the medium, which indicated that salmochelin is bound by siderocalin before siderocalin folds into its final conformation in the cell, and that binding of salmochelin to matured siderocalin is not possible. Salmochelin is mainly produced by pathogenic enterobacteria. Glucosylation of enterobactin may be a mechanism by which these bacteria evade trapping of the enterobactin by siderocalin.

Environmental factors influence the production of enterobactin, salmochelin, aerobactin, and yersiniabactin in Escherichia coli strain Nissle 1917.

The probiotic Escherichia coli strain Nissle 1917 produces four siderophores: the catecholates enterobactin and salmochelin, the hydroxamate aerobactin, and the mixed-type siderophore yersiniabactin. We studied the influence of pH, temperature, and carbon source on the production of these four siderophores. Yersiniabactin and salmochelin were maximally produced under neutral to alkaline conditions (pH 7.0 and 7.6, respectively), whereas aerobactin was maximally produced at a more acidic pH (pH 5.6), which agrees with the slightly higher complex stability of hydroxamates at acidic pH values compared to the catecholates. Under nearly all conditions studied, catecholate siderophore production was higher with glycerol than with glucose as the carbon source. Yersiniabactin production was also higher with glycerol as the carbon source at pH 7.0. At 42 degrees C, strain Nissle 1917 grew poorly or not at all because of the iron-limiting conditions. In a competition experiment between wild-type strain Nissle 1917 and a mutant of this strain with a deletion in the yersiniabactin operon, the wild-type overgrew the mutant at pH 7.0 and 7.6 and not at pH 5.6. These results agree with yersiniabactin production being of greater advantage at neutral and slightly alkaline pH values. The production of four siderophores may help the probiotic E. coli Nissle 1917 to compete with other E. coli strains in the colon. The probiotic strain Nissle 1917 used in our experiments has many characteristics in common with uropathogenic E. coli and other pathogenic strains which also secrete these siderophores. Uropathogenic E. coli strains may need the multitude of siderophores to adapt to the pH of urine, which varies between pH 4.6 and 8.0.

Functions of the siderophore esterases IroD and IroE in iron-salmochelin utilization.

The siderophore salmochelin is produced under iron-poor conditions by Salmonella and many uropathogenic Escherichia coli strains. The production of salmochelin, a C-glucosylated enterobactin, is dependent on the synthesis of enterobactin and the iroBCDEN gene cluster. An E. coli IroD protein with an N-terminal His-tag cleaved cyclic salmochelin S4 to the linear trimer salmochelin S2, the dimer salmochelin S1, and the monomers dihydroxybenzoylserine and C-glucosylated dihydroxybenzoylserine (salmochelin SX, pacifarinic acid). The periplasmic IroE protein was purified as a MalE-IroE fusion protein. This enzyme degraded salmochelin S4 and ferric-salmochelin S4 to salmochelin S2 and ferric-salmochelin S2, respectively. In E. coli, uptake of ferric-salmochelin S4 was dependent on the cleavage by IroE, and independent of the FepBDGC ABC transporter in the cytoplasmic membrane. IroC, which has similarities to ABC-multidrug-resistance proteins, was necessary for the uptake of salmochelin S2 from the periplasm into the cytoplasm. IroE did not function as a classical binding protein since salmochelin S2 was taken up in the absence of a functional IroE protein. IroC mediated the uptake of iron via enterobactin in a fepB mutant. IroE was also necessary in this case for the uptake of ferric-enterobactin, which indicated that only the linear degradation products of enterobactin were taken up via IroC. PfeE, the Pseudomonas aeruginosa IroE homologue, was cloned, and its enzymic activity was shown to be very similar to that of IroE. It is suggested that homologues in other bacteria are also periplasmic IroE-type esterases of siderophores.

The detection of salmochelin and yersiniabactin in uropathogenic Escherichia coli strains by a novel hydrolysis-fluorescence-detection (HFD) method.

Escherichia coli strains produce a variety of structurally different siderophores of which enterobactin, aerobactin and yersiniabactin have been reported earlier to occur in strains of extraintestinal infections. In uropathogenic E. coli (UPEC) strains novel siderophores, named salmochelins, have recently been identified which contain C-glucosylated 2,3-dihydroxybenzoyl-L-serine (glucosyl-DHB-serine) residues connected in a linear (mono-, di- , trimeric) or cyclic form. We report here on a fast and simple hydrolysis-fluorescence-detection (HFD) method, based on identification of C-glucosylated dihydroxybenzoic acid (glucosyl-DHB). Salmochelin containing culture filtrates were bound to DEAE cellulose spin columns, hydrolyzed and the breakdown products were subsequently identified by HPLC or thin layer chromatography (TLC). The hydrolysis products can be easily detected by their fluorescence, either during HPLC separation connected to a fluorescence detector or after TLC on cellulose plates viewed under a UV254 or UV365 lamp. While DHB originates from the hydrolysis of enterobactin and salmochelin, glucosyl-DHB is only found as a characteristic hydrolysis product of salmochelins (S1, S2, S4). The HFD method allows detection of salmochelin in the presence of other siderophores, such as enterobactin, aerobactin and yersiniabactin. Several clinical UPEC isolates containing the iroN gene cluster were analyzed by this procedure, showing that all isolates were glucosyl-DHB positive indicating salmochelin production, while a collection of other pathogenic E. coli strains (EHEC, EIEC, ETEC, EAggEC and EPEC) were glucosyl-DHB negative. In addition, the HFD method allowed the identification of yersiniabactin due to a fluorescent salicylate-containing degradation product.

The structure of salmochelins: C-glucosylated enterobactins of Salmonella enterica.

Salmochelins represent novel carbohydrate containing catecholate siderophores, which are excreted by Salmonella enterica and uropathogenic Escherichia coli strains under low-iron stress. While previous analytical data showed salmochelins to contain 2,3-dihydroxybenzoyl-L-serine and glucose, the molecular structure remained elusive. Structure elucidation with electrospray ionization-Fourier transform ion cyclotron resonance-mass spectrometry (ESI-FTICR-MS), GC-MS and 2D-NMR now revealed that salmochelins are enterobactin-related compounds, which are beta-C-glucosylated at the 5-position of a 2,3-dihydroxybenzoyl residue. The key compound salmochelin S4 is a twofold beta-C-glucosylated enterobactin analogue. Comparison of partial structures of salmochelin with a C-glycosylated compound previously characterized by another group strongly suggest that salmochelins represent the long sought compounds termed Salmonella resistance factors (SRF) or pacifarins. Transformation of iro-genes into enterobactin-producing E. coli K12 confers the ability to produce salmochelins. A detailed analysis proved iroB to be the sole gene with glycosyltransferase activity necessary for salmochelin production. Salmochelins compared to enterobactin are the better siderophores in the presence of serum albumin. This may indicate for salmochelins a considerably more important role for pathogenic processes in certain Escherichia coli and Salmonella infections than formerly assigned to enterobactin. This conclusion is supported by the location of the iro genes on pathogenicity islands of uropathogenic E. coli strains.