Ex vivo analysis of synergistic anion binding to FbpA in Gram-negative bacteria

Ferric binding protein, FbpA, is a member of the transferrin superfamily whose function is to move an essential nutrient, iron, across the periplasm and into the cytosol through formation of a ternary complex containing Fe (3+) and a synergistic anion, X. Here we utilize SUPREX ( stability of unpurified proteins from rates of H/D exchange) to determine the identification and distribution of the synergistic anion in FeFbpA-X species in periplasmic preparations from Gram-negative bacteria. SUPREX is a mass spectrometry-based technique uniquely suited for thermodynamic analyses of protein-ligand complexes in complex biological mixtures such as periplasmic preparations. Model binary mixtures of FeFbpA-Cit and FeFbpA-PO 4 were initially characterized by SUPREX due to the likely presence of citrate and phosphate ions in the periplasm. Ex vivo SUPREX analyses were performed on FeFbpA-X species overexpressed in an Escherichia coli cell line and on endogenous FeFbpA-X species in Neisseria gonorrheae. Detected in the E. coli periplasmic extract were two distinct populations of FbpA, including one in which the protein was unliganded (i.e., apoFbpA) and one in which the protein was bound to iron and the synergistic anion, phosphate (i.e., FeFbpA-PO 4). FeFbpA-PO 4 was the only population of FbpA molecules detected in the N. gonorrheae periplasmic extract. This work provides the first determination of the identity of the in vivo anion bound to FeFbpA-X in the periplasm and substantiates the hypothesis that the synergistic anion plays a structural and functional role in FbpA-mediated transport of iron across the periplasm and into the cytosol.     

Construction and Characterization of Versatile Cloning Vectors for Efficient Delivery of Native Foreign Proteins to the Periplasm ofEscherichia coli

Induction of the wild type cholera toxin operon (ctxAB) from multicopy clones inEscherichia coliinhibited growth and resulted in low yields of cholera toxin (CT). We found that production of wild type CT or its B subunit (CT-B) as a periplasmic protein was toxic forE. coli,but by replacing the native signal sequences of both CT-A and CT-B with the signal sequence from the B subunit ofE. coliheat-labile enterotoxin LTIIb we succeeded for the first time in producing CT holotoxin in high yield inE. coli.Based on these findings, we designed and constructed versatile cloning vectors that use the LTIIb-B signal sequence to direct recombinant native proteins with high efficiency to the periplasm ofE. coli.We confirmed the usefulness of these vectors by producing two other secreted recombinant proteins. First, usingphoAfromE. coli,we demonstrated that alkaline phosphatase activity was 17-fold greater when the LTIIb-B signal sequence was used than when the native leader for alkaline phosphatase was used. Second, using thepspAgene that encodes pneumococcal surface protein A fromStreptococcus pneumoniae,we produced a 299-residue amino-terminal fragment of PspA inE. coliin large amounts as a soluble periplasmic protein and showed that it was immunoreactive in Western blots with antibodies against native PspA. The vectors described here will be useful for further studies on structure–function relationships and vaccine development with CT and PspA, and they should be valuable as general tools for delivery of other secretion-competent recombinant proteins to the periplasm inE. coli.     

Differential effect of dsbA and dsbC mutations on extracellular enzyme secretion in Erwinia chrysanthemi

An Erwinia chrysanthemi gene able to complement an Escherichia coli dsbA mutation has been cloned and sequenced. This gene codes for a periplasmic protein with disulphide isomerase activity that has 69% identity and 94% similarity with the E. coli DsbA protein. An E. chrysanthemi dsbA-uidA fusion mutant has been constructed. dsbA expression seems to be constitutive. This mutant has multiple phenotypes resulting from the absence of disulphide bond formation in periplasmic and secreted proteins. Pectate lyases and the cellulase EGZ are rapidly degraded in the periplasm of the dsbA mutant. E. chrysanthemi synthesizes another periplasmic protein with disulphide isomerase activity, namely DsbC. The dsbC gene introduced on a multicopy plasmid in a dsbA mutant was only partially able to restore EGZ secretion, indicating that even if DsbA and DsbC possess disulphide oxydoreductase activity, they are not completely interchangeable. Moreover, pectate lyases expressed in an E. coli dsbA mutant were very instable but their stability was unaffected in a dsbC mutant. These results indicate that DsbA and DsbC could have different substrate specificities.     

Characterization of a novel method for the production of single-span membrane proteins in Escherichia coli

The large-scale production and isolation of recombinant protein is a central element of the biotechnology industry and many of the products have proved extremely beneficial for therapeutic medicine. Escherichia coli is the microorganism of choice for the expression of heterologous proteins for therapeutic application, and a range of high-value proteins have been targeted to the periplasm using the well characterized Sec protein export pathway. More recently, the ability of the second mainstream protein export system, the twin-arginine translocase, to transport fully-folded proteins into the periplasm of not only E. coli, but also other Gram-negative bacteria, has captured the interest of the biotechnology industry. In this study, we have used a novel approach to block the export of a heterologous Tat substrate in the later stages of the export process, and thereby generate a single-span membrane protein with the soluble domain positioned on the periplasmic side of the inner membrane. Biochemical and immuno-electron microscopy approaches were used to investigate the export of human growth hormone by the twin-arginine translocase, and the generation of a single-span membrane-embedded variant. This is the first time that a bonafide biotechnologically relevant protein has been exported by this machinery and visualized directly in this manner. The data presented here demonstrate a novel method for the production of single-span membrane proteins in E. coli.     

Protein folding in the periplasm of Escherichia coli

With the discovery of molecular chaperones and the development of heterologous gene expression techniques, protein folding in bacteria has come into focus as a potentially limiting factor in expression and as a topic of interest in its own right. Many proteins of importance in biotechnology contain disulphide bonds, which form in the Escherichia coli periplasm, but most work on protein folding in the periplasm of E. coli is very recent and is often speculative. This MicroReview gives a short overview of the possible fates of a periplasmic protein from the moment it is translocated, as well as of the E. coli proteins involved in this process. After an introduction to the specific physiological situation in the periplasm of E. coli, we discuss the proteins that might help other proteins to obtain their correctly folded conformation — disulphide isomerase, rotamase, parts of the translocation apparatus and putative periplasmic chaperones — and briefly cover the guided assembly of multi-subunit structures. Finally, our MicroReview turns to the fate of misfolded proteins: degradation by periplasmic proteases and aggregation phenomena.     

Assembly proteins of CS1 pili of enterotoxigenic Escherichia coli

Some strains of enterotoxigenic Escherichia coli associated with human diarrhoeal disease produce a class of pili represented by those called CS1. For the assembly of the major-pilin subunit, CooA, into pili, each of four linked genes, cooB,A,C, and D, is required. In this study, we have determined the subcellular localization of CooB, C and D, and investigated the molecular interactions of these proteins using specific antisera. CooD appears to be an integral pilus protein because it co-purifies with, and is strongly associated with, CS1 pili. In keeping with its role as an assembly protein, the CooD minor pilin (when overexpressed in CS1-piliated strains) was detected in periplasmic inter-molecular complexes with the major-pilin subunit CooA. CooB is an assembly protein found exclusively in the periplasm of CS1-piliated strains. CooB also forms periplasmic intermolecular complexes with CooA, but does not constitute part of the final pilus structure. Immunoblot analysis of cell fractions showed that CooC is an outer membrane protein of CS1-piliated E. coli. Based on this information, we have proposed a model for CS1 -pilus assembly which is very similar to the model for polymerization of the PapA pilin of uropathogenic E. coli. As the assembly proteins of Pap and CS1 pili are structurally unrelated, this may represent a case of convergent evolution.     

Escherichia coli “TatExpress” strains super‐secrete human growth hormone into the bacterial periplasm by the Tat pathway

Numerous high‐value proteins are secreted into the Escherichia coli periplasm by the General Secretory (Sec) pathway, but Sec‐based production chassis cannot handle many potential target proteins. The Tat pathway offers a promising alternative because it transports fully folded proteins; however, yields have been too low for commercial use. To facilitate Tat export, we have engineered the TatExpress series of super‐secreting strains by introducing the strong inducible bacterial promoter, ptac , upstream of the chromosomal tatABCD operon, to drive its expression in E. coli strains commonly used by industry (e.g., W3110 and BL21). This modification significantly improves the Tat‐dependent secretion of human growth hormone (hGH) into the bacterial periplasm, to the extent that secreted hGH is the dominant periplasmic protein after only 1 hr induction. TatExpress strains accumulate in excess of 30 mg L^?1 periplasmic recombinant hGH, even in shake flask cultures. A second target protein, an scFv, is also shown to be exported at much higher rates in TatExpress strains.

     

In vivo and in vitro studies on interactions between the components of the hemolysin (HlyA) secretion machinery of Escherichia coli

The glycopeptide antibiotic vancomycin blocks cell wall synthesis in Escherichia coli only when it can reach its target site in the periplasm. In vivo, sensitivity to vancomycin is enhanced in the presence of the hemolysin (hly) determinant of E. coli or its translocator portion hlyBD. Two different mutations in hlyD alter the cell's susceptibility to vancomycin: mutations in the tolC-homologous region of hlyD increase vancomycin resistance, whereas mutations at the 3′-terminus of hlyD lead to hypersensitivity to vancomycin and to the accumulation of large periplasmic and cytoplasmic pools of this antibiotic in E. coli. These effects are only observed in the presence of functional HlyB and TolC, the two other components of the hemolysin secretion machinery. A defect in TolC causes hyperresistance to vancomycin, even when present together with a mutant HlyD protein which in the presence of TolC renders E. coli hypersensitive to vancomycin. Lipid bilayer experiments in vitro revealed specific interactions between TolC and vancomycin or HlyD protein. Second-site suppressor mutations in hlyD and hlyB were obtained, which abolish the hypersensitive phenotype caused by the 3′-terminal mutations in hlyD. Our results are compatible with the idea that (a) TolC, together with the TolC-homologous part of HlyD, forms a pore in the outer membrane through which hemolysin is released and vancomycin taken up; and (b) the C-terminal sequence of HlyD interacts with periplasmic loop(s) of HlyB to form a closed channel spanning the periplasm. Received: 7 April 1997 / Accepted: 28 May 1997     

SlyA, a regulatory protein from Salmonella typhimurium, induces a haemolytic and pore-forming protein in Escherichia coli

A chromosomal fragment from Salmonella typhimurium, when cloned in Escherichia coli, generates a haemolytic phenotype. This fragment carries two genes, termed slyA and slyB. The expression of slyA is sufficient for the haemolytic phenotype. The haemolytic activity of E. coli carrying multiple copies of slyA is found mainly in the cytoplasm, with some in the periplasm of cells grown to stationary phase, but overexpression of SlyB, a 15 kDa lipoprotein probably located in the outer membrane, may lead to enhanced, albeit unspecific, release of the haemolytic activity into the medium. Polyclonal antibodies raised against a purified SlyA-HlyA fusion protein identified the over-expressed monomeric 17 kDa SlyA protein mainly in the cytoplasm of E. coli grown to stationary phase, although smaller amounts were also found in the periplasm and even in the culture supernatant. However, the anti-SlyA antibodies reacted with the SlyA protein in a periplasmic fraction that did not contain the haemolytic activity. Conversely, the periplasmic fraction exhibiting haemolytic activity did not contain the 17 kDa SlyA protein. Furthermore, S. typhimurium transformed with multiple copies of the slyA gene did not show a haemolytic phenotype when grown in rich culture media, although the SlyA protein was expressed in amounts similar to those in the recombinant E. coli strain. These results indicate that SlyA is not itself a cytolysin but rather induces in E. coli (but not in S. typhimurium) the synthesis of an uncharacterised, haemolytically active protein which forms pores with a diameter of about 2.6 nm in an artificial lipid bilayer. The SlyA protein thus seems to represent a regulation factor in Salmonella, as is also suggested by the similarity of the SlyA protein to some other bacterial regulatory proteins. slyA- and slyB-related genes were also obtained by PCR from E. coli, Shigella sp. and Citrobacter diversus but not from several other gram-negative bacteria tested.     

Cellular localization and export of the soluble haemolysin of Vibrio cholerae El Tor

Summary The cellular location of the haemolysin of Vibrio cholerae El Tor strain 017 has been analyzed. This protein is found both in the periplasmic space and the extracellular medium in Vibrio cholerae. However, when the cloned gene, present on plasmid pPM431, is introduced into E. coli K-12 this protein remains localized predominantly in the periplasmic space with no activity detected in the extracellular medium. Mutants of E. coli K-12 (tolA and tolB) which leak periplasmic proteins mimic excretion and release the haemolysin into the growth medium. Secretion of haemolysin into the periplasm is independent of perA (envZ) and in fact, mutants in perA (envZ) harbouring pPM431 show hyperproduction of periplasmic haemolysin. These results in conjunction with those for other V. cholerae extracellular proteins suggest that although E. coli K-12 can secrete these proteins into the periplasm, it lacks a specific excretion mechanism, present in V. cholerae, for the release of soluble proteins into the growth medium.     

Intracellular localization of the superoxide dismutases of Escherichia coli: a reevaluation.

All of the superoxide dismutase isozymes of Escherichia coli have been shown to occur in the cell matrix, and none have been found in the periplasm. This was the case with both E. coli B and E. coli K-12, whether grown on a low phosphate medium or on a Trypticase soy-yeast extract medium. Alkaline phosphatase was used as a marker of the periplasm; adenosine deaminase and glucose 6-phosphate dehydrogenase were used as matrix markers, and consistent results were obtained by osmotic shock, spheroplast formation, and use of a diazonium salt that penetrates the periplasm but cannot cross the plasma membrane. A previous report that the iron-containing superoxide dismutase of E. coli is a periplasmic enzyme is now seen to have been in error.     

Periplasmic production of native human proinsulin as a fusion to E. coli ecotin

Native proinsulin belongs to the class of the difficult-to-express proteins in Escherichia coli. Problems mainly arise due to its small size, a high proteolytic decay, and the necessity to form a native disulfide pattern. In the present study, human proinsulin was produced in the periplasm of E. coli as a fusion to ecotin, which is a small periplasmic protein of 16 kDa encoded by the host, containing one disulfide bond. The fusion protein was secreted to the periplasm and native proinsulin was determined by ELISA. Cultivation parameters were studied in parallel batch mode fermentations using E. coli BL21(DE3)Gold as a host. After improvement of fed-batch high density fermentation conditions, 153 mg fusion protein corresponding to 51.5mg native proinsulin was obtained per L. Proteins were extracted from the periplasm by osmotic shock treatment. The fusion protein was purified in one step by ecotin affinity chromatography on immobilized trypsinogen. After thrombin cleavage of the fusion protein, the products were separated by Ni-NTA chromatography. Proinsulin was quantified by ELISA and characterized by mass spectrometry. To evaluate the influence of periplasmic proteases, the amount of ecotin-proinsulin was determined in E. coli BL21(DE3)Gold and in a periplasmic protease deficient strain, E. coli SF120.     

Stable periplasmic secretion intermediate in the general secretory pathway of Escherichia coli.

The secretion of the Klebsiella oxytoca cell surface lipoprotein pullulanase involves translocation across the cytoplasmic and outer membranes of the Gram-negative bacterial cell envelope. A variant of pullulanase was created by fusing the signal peptide-encoding 5' region of the Escherichia coli gene for periplasmic MalE protein to the 3' end of the pulA gene encoding almost the entire mature part of pullulanase. When produced in E. coli carrying the malE-pulA gene fusion on a high copy number plasmid and the complete set of genes specifically required for pullulanase secretion on a second plasmid, the hybrid protein differed from wild-type pullulanase as follows: (i) it was not fatty-acylated; (ii) it was apparently processed by LepB signal peptidase rather than by LspA lipoprotein signal peptidase; (iii) it was released into the periplasm and was only slowly transported across the outer membrane, and (iv) it was released directly into the medium rather than via the usual surface-anchored intermediate. The hybrid protein was secreted more rapidly when malE-pulA was expressed from a low copy number plasmid. The two steps in the secretion pathway could be totally uncoupled by expressing first the malE-pulA gene fusion and then the cognate secretion genes. These results show that fatty-acylation of wild-type PulA is not essential for secretion but may improve its efficiency when large amounts of the protein are produced, that the two steps in secretion can occur quite independently and that the periplasmic intermediate can persist for long periods under certain circumstances.     

Levansucrase from Acetobacter diazotrophicus SRT4 Is Secreted via Periplasm by a Signal-Peptide-Dependent Pathway

Acetobacter diazotrophicus SRT4 secretes a constitutive levansucrase (LsdA) (EC 2.4.1.10) that is responsible for sucrose utilization. Immunogold electron microscopical studies revealed that LsdA accumulates in the periplasm before secretion. The periplasmic and extracellular forms of the enzyme were purified to homogeneity. Both proteins exhibited similar physical and biochemical characteristics indicating that LsdA adopts its final conformation in the periplasm. The N-terminal sequence of mature LsdA was pGlu-Gly-Asn-Phe-Ser-Arg as determined by PSD-MALDI-TOFMS (post-source decay—matrix-assisted laser desorption/ionization—time-of-flight mass spectrometry). Comparison of this sequence with the predicted precursor protein revealed the cleavage of a 30-residue typical signal peptide followed by the formation of the pyroglutamic acid (pGlu) residue. Thus, in contrast with other Gram-negative bacteria, A. diazotrophicus secretes levansucrase by a signal-peptide-dependent mechanism. Received: 24 March 1999 / Accepted: 30 April 1999     

A novel fusion protein system for the production of native human pepsinogen in the bacterial periplasm

Human pepsinogen is the secreted inactive precursor of pepsin. Under the acidic conditions present in the stomach it is autocatalytically cleaved into the active protease. Pepsinogen contains three consecutive disulfides, and was used here as a model protein to investigate the production of aspartic proteases in the Escherichia coli periplasm. Various N-terminal translocation signals were applied and several different expression vectors were tested. After fusion to pelB, dsbA or ompT signal peptides no recombinant product could be obtained in the periplasm using the T7 promoter. As a new approach, human pepsinogen was fused to E. coli ecotin (E. coli trypsin inhibitor), which is a periplasmic homodimeric protein of 142 amino acids per monomer containing one disulfide bridge. The fusion protein was expressed in pTrc99a. After induction, the ecotin-pepsinogen fusion protein was translocated into the periplasm and the ecotin signal peptide was cleaved. Upon acid treatment, the fusion protein was converted into pepsin, indicating that pepsinogen was produced in its native form. In shake flasks experiments, the amount of active fusion protein present in the periplasm was 100 microg per litre OD 1, corresponding to 70 microg pepsinogen. After large scale cultivation, the fusion protein was isolated from the periplasmic extract. It was purified to homogeneity with a yield of 20%. The purified protein was native. Acid-induced activation of the fusion protein proceeded very fast. As soon as pepsin was present, the ecotin part of the fusion protein was rapidly digested, followed by a further activation of pepsinogen.     

Development of a generic approach to native metalloproteomics: application to the quantitative identification of soluble copper proteins in Escherichia coli

A combination of techniques to separate and quantify the native proteins associated with a particular transition metal ion from a cellular system has been developed. The procedure involves four steps: (1) labeling of the target proteins with a suitable short-lived radioisotope (suitable isotopes are ⁶⁴Cu, ⁶⁷Cu, ¹⁸⁷W, ⁹⁹Mo, ⁶⁹Zn, ⁵⁶Mn, ⁶⁵Ni); (2) separation of intact soluble holoproteins using native isoelectric focusing combined with blue native polyacrylamide gel electrophoresis into native–native 2D gel electrophoresis; (3) spot visualization and quantification using autoradiography; and (4) protein identification with tandem mass spectrometry. The method was applied to the identification of copper proteins from a soluble protein extract of wild-type Escherichia coli K12 using the radioisotope ⁶⁴Cu. The E. coli protein CueO, which has previously been only identified as a multicopper oxidase following homologous overexpression, was now directly detected as a copper protein against a wild-type background at an expression level of 0.007% of total soluble protein. The retention of the radioisotope by the copper proteins throughout the separation process corroborates the method to be genuinely native. The procedure developed here can be applied to cells of any origin, and to any metal having suitable radioisotopes. The finding that the periplasmic protein CueO is the only major form of soluble protein bound copper in E. coli strengthens the view that the bacterial periplasm contains only a few periplasmic copper proteins, and that the cytosol is devoid of copper proteins. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Identification of the Periplasmic Cobalamin-Binding Protein BtuF of Escherichia coli

Cells of Escherichia coli take up vitamin B(12) (cyano-cobalamin [CN-Cbl]) and iron chelates by use of sequential active transport processes. Transport of CN-Cbl across the outer membrane and its accumulation in the periplasm is mediated by the TonB-dependent transporter BtuB. Transport across the cytoplasmic membrane (CM) requires the BtuC and BtuD proteins, which are most related in sequence to the transmembrane and ATP-binding cassette proteins of periplasmic permeases for iron-siderophore transport. Unlike the genetic organization of most periplasmic permeases, a candidate gene for a periplasmic Cbl-binding protein is not linked to the btuCED operon. The open reading frame termed yadT in the E. coli genomic sequence is related in sequence to the periplasmic binding proteins for iron-siderophore complexes and was previously implicated in CN-Cbl uptake in SALMONELLA: The E. coli yadT product, renamed BtuF, is shown here to participate in CN-Cbl uptake. BtuF protein, expressed with a C-terminal His(6) tag, was shown to be translocated to the periplasm concomitant with removal of a signal sequence. CN-Cbl-binding assays using radiolabeled substrate or isothermal titration calorimetry showed that purified BtuF binds CN-Cbl with a binding constant of around 15 nM. A null mutation in btuF, but not in the flanking genes pfs and yadS, strongly decreased CN-Cbl utilization and transport into the cytoplasm. The growth response to CN-Cbl of the btuF mutant was much stronger than the slight impairment previously described for btuC, btuD, or btuF mutants. Hence, null mutations in btuC and btuD were constructed and revealed that the btuC mutant had a strong impairment similar to that of the btuF mutant, whereas the btuD defect was less pronounced. All mutants with defective transport across the CM gave rise to frequent suppressor variants which were able to respond at lower levels of CN-Cbl but were still defective in transport across the CM. These results finally establish the identity of the periplasmic binding protein for Cbl uptake, which is one of few cases where the components of a periplasmic permease are genetically separated.     

Isolation of a Periplasmic Molecular Chaperone-Like Protein of Rhodobacter sphaeroides f. sp. denitrificans That Is Homologous to the Dipeptide Transport Protein DppA of Escherichia coli

A periplasmic protein has been found to prevent aggregation of the acid-unfolded dimethyl sulfoxide reductase (DMSOR), the periplasmic terminal reductase of dimethyl sulfoxide respiration in the phototroph Rhodobacter sphaeroides f. sp. denitrificans, in a manner similar to that of the Escherichia coli chaperonin GroEL (Matsuzaki et al., Plant Cell Physiol. 37:333–339, 1996). The protein was isolated from the periplasm of the phototroph. It had a molecular mass of 58 kDa and had no subunits. The sequence of 14 amino-terminal residues of the protein was completely identical to that of the periplasmic dipeptide transport protein (DppA) of E. coli. The 58-kDa protein prevented aggregation to a degree comparable to that of GroEL on the basis of monomer protein. The 58-kDa protein also decreased aggregation of guanidine hydrochloride-denatured rhodanese, a mitochondrial matrix protein, during its refolding upon dilution. The 58-kDa protein is a kind of molecular chaperone and could be involved in maintaining unfolded DMSOR, after secretion of the latter into the periplasm, in a competent form for its correct folding.     

Fate of ferrisiderophores after import across bacterial outer membranes: different iron release strategies are observed in the cytoplasm or periplasm depending on the siderophore pathways

Siderophore production and utilization is one of the major strategies deployed by bacteria to get access to iron, a key nutrient for bacterial growth. The biological function of siderophores is to solubilize iron in the bacterial environment and to shuttle it back to the cytoplasm of the microorganisms. This uptake process for Gram-negative species involves TonB-dependent transporters for translocation across the outer membranes. In Escherichia coli and many other Gram-negative bacteria, ABC transporters associated with periplasmic binding proteins import ferrisiderophores across cytoplasmic membranes. Recent data reveal that in some siderophore pathways, this step can also be carried out by proton-motive force-dependent permeases, for example the ferrichrome and ferripyochelin pathways in Pseudomonas aeruginosa. Iron is then released from the siderophores in the bacterial cytoplasm by different enzymatic mechanisms depending on the nature of the siderophore. Another strategy has been reported for the pyoverdine pathway in P. aeruginosa: iron is released from the siderophore in the periplasm and only siderophore-free iron is transported into the cytoplasm by an ABC transporter having two atypical periplasmic binding proteins. This review presents recent findings concerning both ferrisiderophore and siderophore-free iron transport across bacterial cytoplasmic membranes and considers current knowledge about the mechanisms involved in iron release from siderophores.