Hydroxamic acids ferrioxamines

Mikes and Turkova have given a classification of naturally occurring hydroxamic acids in terms of their biological function or activity. They have distinguished (a) growth factors, e.g., ferri-chromes, mycobactin, and ferrioxamines, ferrichrysins, ferrirubins, etc. (6) antibiotics, e.g, aspergillic acid, mycelianamide, albomycin, nocardamine and (c) microbial pigments such as pulcherrimin. 

The ferrioxamines form a large group of ferric trihydroxamates composed of residues of acetic acid, succinic acid, l-amino-5-hydroxyl-aminopentane, and l-amino-4-hydroxylaminobutane. Of the.se, only ferrioxamines E (14) and D2 (15) are formally cyclic hydroxamic acids. 

The po.ssible role of a chelate reductase for iron uptake from microbial siderophores has been examined for several plant species (30,47). With certain microbial siderophores such as rhizoferrin and rhodotorulic acid, the reductase may easily cleave iron from the siderophore to allow subsequent uptake by the ferrous iron transporter. However, with the hydroxamate siderophore, ferrioxamine B, which is produced by actinomycetes and u.sed by diverse bacteria and fungi, it has been shown that the iron stress-regulated reductase is not capable... 

Ferrioxamines Hydroxamic acid 3 Species of Nocardia, Micromon-ospora, Streptomyces, and Actinomyces... 

Fig. 19. Plot of redox potentials (Ey2) as a function of pFe3+ values for a series of hexadentate, tetradentate, and bidentate hydroxamic acid siderophores and siderophore mimics. Data from Table V. Legend 1 — ferrioxamine E 2 — ferrioxamine B (4) 3 — H.aLjf4 (11) 4 — H >L 36 (12) 5 - coprogen 6 - ferricrocin 7 - ferrichrome (6) 8 - alcaligin 9 -rhodotorulic acid (3) 10 — NMAHA 11 — AHA 12 — Ly-AHA.

Fig. 29. Ternary complex formed between ferrioxamine B (4) and lauroyl hydroxamic acid.

Natural and biomimetic hydroxamic acid based siderophores TABLE 2. Natural ferrioxamines and their structural variations... 

Schwarzenbach, G. and K. Schwarzenbach Hydroxamate complexes, I. The stability of the iron (III) complex of simple hydroxamic acids and ferrioxamine B. Helv. Chim. Acta 46, 1390 (1963). 

Recent evidence has been gathered that indicates that extracellular iron reduction and iron uptake in some phytoplankton may also be linked. Anderson and Morel (1981) showed that the Fe(II) complexing agent BPDS inhibited l e(lll) uptake by T. weissflogii in medium spiked with Fe(Ill)EDTA, suggesting a role for Fe reduction in making Fe more available to the cells. In Chlorella vulgaris, the Fe in the hydroxamate complexes ferrioxamine B and rhodotorulic acid is taken up only by iron-starved cells, and Fe reduction also appears to be involved in this process (Allnutt and Bonner, 1987). 

As mentioned above, transport of siderophores across the cytoplasmic membrane is less specific than the translocation through the outer membrane. In E. coli three different outer membrane proteins (among them FepA the receptor for enterobactin produced by most E. coli strains) recognise siderophores of the catechol type (enterobactin and structurally related compounds), while only one ABC system is needed for the passage into the cytosol. Likewise, OM receptors FhuA, FhuE, and Iut are needed to transport a number of different ferric hydroxamates, whereas the FhuBCD proteins accept a variety of hydroxamate type ligands such as albomycin, ferrichrome, coprogen, aerobactin, shizokinen, rhodotorulic acid, and ferrioxamine B [165,171], For the vast majority of systems, the substrate specificity has not been elucidated, but it can be assumed that many siderophore ABC permeases might be able to transport several different but structurally related substrates. 

Ferrioxamines B and E are prime examples of the linear and cyclic species, respectively. Several members of the series have been prepared by total synthesis, thus establishing the sequence of the contained units (For example, four isomers could be constructed from the hydrolytic products of ferrioxamine B). The three hydroxamate functions must be spatially located so as to form a stable, intramolecular hexa-dentate ferric chelate. Acetylation of ferrioxamine B affords ferrioxa-mine Di ferrioxamine G corresponds to component B with succinic replacing acetic acid cyclization of G yields ferrioxamine E components Ai and D2 carry l-amino-4-hydroxyaminobutane in place of a residue of the next higher homologue. 

The second main class of Fem-specific sequestering agents (siderophores) responsible for the acquisition and assimilation of iron employ hydroxamate ligating groups (34).157158 186 Two important subclasses are the ferrioxamines and the ferrichromes (Figure 5). Examples are ferrioxamine B, a linear trihydroxamic acid and ferrichrome A, a cyclic hexapeptide carrying three hydroxamate-containing side chains. 

After Fe + siderophores have docked at the binding pocket of the outer-membrane receptors of E. colt, translocation into the periplasmic space is mediated by the TonB complex. Once released into the periplasm, siderophores are rapidly bound by the specific periplasmic binding proteins FhuD (hydroxamate siderophores), FepB (enterobactin), and FecB (ferric dicitrate).FhuD, for example, exhibits a broad substrate specificity for a variety of hydroxamate siderophores including ferrichrome, coprogen, aerobactin, ferrioxamine B, shizokinen, rhodotorulic acid, and the antibiotic albomycin. The dissociation constants of FhuD with these siderophores range from 0.3 to 5.4 X-ray structures of FhuD... 

Figure 1 Representative siderophores of the hydroxamate and catecholate classes. The hydroxamates are synthesized from the amino acid ornithine that has been modified through hydroxylation and acetylation. Ferrichrome (a) is a prototypical example of the tri-hydroxamate class. Structurally, ferrichrome is a cyclic hexapeptide that consists of three modified ornithine residues (each of which has a hydroxamate side chain) and three glycines. Ferrichrome coordinates ferric iron through its three bidentate hydroxamate side chains. Triacetylfusarinine C (b) is also a cyclic tri-hydroxamate, but the three modified ornithine residues are joined by ester linkages rather than by peptide linkages. Ferrioxamine B (c) is a linear tri-hydroxamate consisting of three peptide-huked modified ornithine residues. Enterobactin (d) is a prototypical example of a catecholate siderophore. It consists of a tri-ester ring from which extend three side chains of chhydroxybenzoyl serine. Each of these siderophores binds ferric iron in a hexadentate manner, which results in full saturation of d orbitals and a very stable complex. Ferric forms are shown in (a) and (b). Desferri-forms are shown in (c) and (d)...

The first synthesis of a siderophore was the preparation of ferrioxamine B over 20 years ago in order to confirm the chemical structure of this natural product67). Synthesis of the other hydroxamate containing siderophores has as a central problem preparation of the constituent to-N-hydroxy amino acid in an optically pure form. The most important such subunit in hydroxamate siderophores is Ns-hydroxy ornithine. This is a chiral building block of the diketopiperazine-containing siderophores (rhodo-torulic acid 68), dimerum acid 69), coprogen 70) and coprogen B 69>), the cyclic hexa-peptides of the ferrichrome family27), the fusarinines 71 -73) and the antibiotic ferri-chrome derivatives albomycines Sl5 S2 and e 61-62). 

Raymond and co-workers have synthesized and separated optical and geometrical isomers of simple tris hydroxamate chroniium(III) and tris phenolate chromium(III) or rhodium(III) complexes and assigned the absolute configurations of these isomers based on criteria such as chromatographic behavior due to differences in dipole moment, theoretical symmetry considerations, and X-ray crystallographic data 174). The absolute configuration of isomers of chromium(III) complexes of ferrichrome, ferrichrysin 175), ferrioxamine B and Dx 176), rhodotorulic acid 177), enterobactin 178),... 

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