Pyoverdine

Pyoverdines (alternatively, and less commonly, spelled as pyoverdins) are fluorescent siderophores produced by certain pseudomonads. Pyoverdines are important virulence factors, and are required for pathogenesis in many biological models of infection. Their contributions to bacterial pathogenesis include providing a crucial nutrient (i.e., iron), regulation of other virulence factors (including exotoxin A and the protease PrpL), supporting the formation of biofilms, and are increasingly recognized for having toxicity themselves. Pyoverdines (alternatively, and less commonly, spelled as pyoverdins) are fluorescent siderophores produced by certain pseudomonads. Pyoverdines are important virulence factors, and are required for pathogenesis in many biological models of infection. Their contributions to bacterial pathogenesis include providing a crucial nutrient (i.e., iron), regulation of other virulence factors (including exotoxin A and the protease PrpL), supporting the formation of biofilms, and are increasingly recognized for having toxicity themselves. Pyoverdines have also been investigated as 'Trojan Horse' molecules for the delivery of antimicrobials to otherwise resistant bacterial strains, as chelators that can be used for bioremediation of heavy metals, and as fluorescent reporters used to assay for the presence of iron and potentially other metals. Due to their bridging the gaps between pathogenicity, iron metabolism, and fluorescence, pyoverdines have piqued the curiosity of scientists around the world for over 100 years. Like most siderophores, pyoverdine is synthesized and secreted into the environment when the microorganism that produces it detects that intracellular iron concentrations have fallen below a preset threshold. Although iron is the fourth-most abundant element in the Earth's crust, solubility of biologically relevant iron compounds is exceedingly low, and is generally insufficient for the needs of most (but not all) microorganisms. Siderophores, which are typically quite soluble and have exceptionally high avidity for iron (III) (the avidity of some siderophores for iron exceeds 1040 M-1 and many of the strongest avidities ever observed in nature are exhibited by siderophores for iron), help increase bioavailability of iron by pulling it into aqueous solution. In addition to this role, pyoverdine has a number of other functions, including regulating virulence, limiting the growth of other bacterial species (and serving as a sort of antimicrobial) by limiting iron availability, and sequestering other metals and preventing their toxicity. Although many (>100) forms of pyoverdine have been isolated and studied, they all have certain characteristics in common. Each pyoverdine molecule has three parts: a dihydroxyquinoline core, a 6-14 amino acid peptide that varies among strains, and a side chain (usually composed of a 4-5 carbon α-ketoacid from the Krebs/citric acid cycle). The core of pyoverdine is responsible for several of its properties, including its well-known yellowish color and fluorescence. The dihydroxyquinoline core is composed of (1S)-5-amino-2,3-dihydro- 8,9-dihydroxy-1H-pyrimidoquinoline-1-carboxylic acid. This portion of the molecule is invariant amongst all observed pyoverdine molecules. The core is modified by the addition of an amino acid chain of pyoverdine is composed of 6-14 amino acids. The chain of amino acids is built onto the chromophore core, and is synthesized via non-ribosomal peptide synthesis. As is common for non-ribsosomally synthesized peptides, pyoverdine frequently includes D-form amino acids and non-standard amino acids, such as N-5-formyl-N-5-hydroxyornithine. The peptide chain may also be partially (or completely) cyclized. This peptide chain provides the other four aspects of the hexadentate interaction, usually through hydroxamate and/or hydroxycarboxylate groups. This portion of the molecule is also crucial for interaction with the ferripyoverdine receptor (FpvA) that allows ferripyoverdine to be imported into the cell. The peptide chain produced by a given strain of Pseudomonas is currently thought to be invariant. Little is known about the particular function or importance of the ketoacid side chain, but it is well known that pyoverdine molecules with different ketoacids (congeners) co-exist. Ketoacids that have been observed include succinate/succinamide, glutamate, glutarate, malate/malamide, and α-ketoglutarate.