Fluorescent siderophore-based chemosensors: iron(III) quantitative determinations

 A highly sensitive and selective method is described for a rapid and easy determination of iron(III). This procedure is based on fluorimetric detection combined with the attractive properties of siderophores and biomimetic ligands, which are strong and selective ferric chelators. Azotobactin δ, a bacterial fluorescent siderophore, three fluorescent derivatives of desferriferrioxamine B with a linear structure (NBD-, MA-, NCP-desferriferrioxamine B) and one tripodal biomimetic ligand of desferriferrichrome carrying an anthracenyl fluorescent probe were examined. A very efficient static quenching mechanism by iron was observed for all the ligands considered in this work. Our results identify azotobactin δ as the most promising chemosensor of ferric traces in water, more sensitive than the NBD-desferriferrioxamine B fluorescent ligand. Under more lipophilic conditions, the anthryl-desferriferrichrome biomimetic analogue showed similar analytical potential and was found to be more sensitive than the lipophilic MA- and NCP-desferriferrioxamine B. Their detection limits were respectively 0.5 ng mL^–1 for azotobactin δ and 0.6 ng mL^–1 for the anthryl tripodal chelator. The calibration curves were linear over the range 0–95 ng mL^–1 and 0–180 ng mL^–1. Various foreign cations have been examined and only copper(II) and aluminium(III) were shown to interfere when present in similar concentrations as iron(III). The developed procedure using fluorescent siderophores or biomimetic ligands of iron(III) may be applied (1) to monitor iron(III)-dependent biological systems and (2) to determine iron(III) quantitatively in natural waters and in biological systems. Received: 12 September 1998 · Accepted: 19 January 1999     

Azotobacter vinelandii strains of disparate origin produce azotobactin siderophores with identical structures

Summary The yellow green fluorescent siderophore, azotobactin, was purified from cultures of twoAzotobacter vinelandii strains. Structural analysis of azotobactin from the North AmericanA. vinelandii strains O and its capsule negative variant UW (also called OP) revealed that both strains produced azotobactins with identical structures. Moreover, azotobactin produced by these two strains was structurally identical to azotobactin D, the fluorescent siderophore previously isolated from the EuropeanA. vinelandii strain D (CCM 289). Unlike strains of fluorescentPseudomonas which produce structurally diverse pyoverdins, strains ofA. vinelandii of disparate origin produced azotobactins of identical structure. Lactonization of azotobactin did not interfere with the ability of this compound to function as a siderophore.     

Revised structures of the pyoverdins from Pseudomonas putida CFBP 2461 and from Pseudomonas fluorescens CFBP 2392

Several suggestions for structures of the siderophores (pyoverdins) from Pseudomonas spp. can be found in the literature which are based on a FAB mass spectrometric analysis only. Availability of two original strains of two Pseudomonas spp. allowed to re-investigate the structure of their pyoverdins. In both cases the amino acid sequence had to be corrected. In addition, d- and l-amino acids could be identified and located in the peptide chain. The knowledge of the correct structures is important in view of an ongoing study to establish relationships between the nature of the peptide chains of pyoverdins and their recognition by outer membrane proteins.     

Fluorescence assay of non-transferrin-bound iron in thalassemic sera using bacterial siderophore

Transfusional iron overload associated with thalassemia leads to the appearance of non-transferrin-bound iron (NTBI) in blood that is toxic and causes morbidity and mortality via tissue damage. Hence, a highly sensitive and accurate assay of NTBI, with broad clinical application in both diagnosis and validation of treatment regimens for iron overload, is important. An assay based on iron chelation by a high-affinity siderophore, azotobactin, has been developed. The steps consist of blocking of native apotransferrin iron binding sites, mobilization of NTBI, ultrafiltration of all serum proteins, and finally the addition of the probe, which has a chromophore that fluoresces at 490 nm. Binding of Fe³⁺ to azotobactin quenches the fluorescence in a concentration-dependent manner. Measured NTBI levels in 63 sera ranged from 0.07 to 3.24 μM (0.375 ± 0.028 μM [means ± SEM]). It correlated well with serum iron and percentage transferrin saturation but not with serum ferritin. Pearson’s correlation coefficients were found to be 0.6074 (P < 0.0001) and 0.6102 (P < 0.0001) for percentage transferrin saturation and total serum iron, respectively. The low values are due to the patients being under regular chelation therapy even prior to sampling, indicating that the method is sensitive to very low levels of NTBI, allowing a much lower detection limit than the available methods.     

Optical features of the fluorophore azotobactin: Applications for iron sensing in biological fluids

Siderophores are bio‐organic ligands secreted by microbes to chelate and assimilate iron to meet their metabolic requirements. Siderophores and their analogs have tremendous therapeutic and analytical potential including the use as Fe (III) biosensors; however, only few practical applications have been realized. The aim of this study was the optical and biophysical characterization of the siderophore azotobactin (Az) secreted by the nitrogen‐fixing bacteria Azotobacter vinelandii. The peptide exhibited fluorescence in the visible range. Quantum yield and lifetime in excited state were measured to ascertain the sensitivity of the molecule as a fluorescent marker in biochemical assays. Its high affinity toward iron in the ferric state was demonstrated through fluorescence emission quenching studies. The accuracy of azotobactin as biosensing tool was determined by analyzing the levels of iron in biological fluids, particularly in human serum. Furthermore, it was demonstrated that it can be encapsulated in sol–gel matrices without significant loss of its fluorescence signal, thus enabling it suitable for adaptation to optical biosensor for Fe (III).