Siderophores selective iron chelation

The physical and coordination chemistry of hydroxamate-based iron chelators, their thermodynamic, kinetic, structural, spectroscopic and surface properties, have been extensively reviewed Therefore, only selective aspects that are relevant for the design of biomimetic siderophore analogs will be discussed. 

Microbes acquire iron by utilizing very specific, low molecular weight iron chelators called siderophores. The resistance of bacteria to previously effective antibiotics can be circumvented in part by covalent coupling of antibiotics to siderophores. Some synthetic siderophores have been found to possess significant antibacterial activity themselves. They have also been found to have considerable potential as nontoxic, organ selective MRI contrast agents (27). 

As mentioned previously, siderophores must selectively bind iron tightly in order to solubilize the metal ion and prevent hydrolysis, as well as effectively compete with other chelators in the system. The following discussion will address in more detail the effect of siderophore structure on the thermodynamics of iron binding, as well as different methods for measuring and comparing iron-siderophore complex stability. The redox potentials of the ferri-siderophore complexes will also be addressed, as ferri-siderophore reduction may be important in the iron uptake process in biological systems. 

The high efficiency and selectivity of the natural siderophores in binding iron(lll) inspired attempts to develop siderophore analogs with improved iron-scavenging properties amenable for chelation therapy. A most pertinent example is desferrioxamine B (DFO), where low patient compliance generates the need for developing oral means of administration for... 

Some natural antibiotics contain a siderophore structure, for instance, 5i-albomycin 35, which is produced by Streptomyces subtropicus. The linear tripeptide portion chelates Fe(III) and, thereby, is able to utilize the iron-transport system of a range of microorganisms. Subsequent to uptake, peptidases localized in the cytoplasmic membrane hydrolytically release the toxic thioribosyl moiety. In principle, this property can be used for selective drug delivery. Preliminary studies indicated that substantial modification of the siderophore framework can be tolerated by microbial iron-transport systems. Surprisingly, simple modifications can be made to cephalosporin molecules, which endow them with the ability to interact with microorganism iron-transport mechanisms. Thus, simple incorporation of a catechol moiety, as in 36, endows this molecule with enhanced activity against Pseudomonas aeruginosa when compared... 

---