2004
DOI: 10.1128/aem.70.2.831-836.2004
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Degradation Pathway and Generation of Monohydroxamic Acids from the Trihydroxamate Siderophore Deferrioxamine B

Abstract: Siderophores are avid ferric ion-chelating molecules that sequester the metal for microbes. Microbes elicit siderophores in numerous and different environments, but the means by which these molecules reenter the carbon and nitrogen cycles is poorly understood. The metabolism of the trihydroxamic acid siderophore deferrioxamine B by a Mesorhizobium loti isolated from soil was investigated. Specifically, the pathway by which the compound is cleaved into its constituent monohydroxamates was examined. High-perform… Show more

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Cited by 25 publications
(22 citation statements)
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“…Metallophores can be degraded, either microbially (Pierwola et al 2004;Villavicencio and Neilands 1965;Zaya et al 1998) or chemically via photochemical or heterogeneous redox reactions Duckworth and Sposito 2005a;Parker et al 2007). The dominant degradation mechanisms and rates under natural conditions for most metallophores are unknown, but degradation rates presumably depend on a combination of environmental factors, including the size and composition of the microbial community (von Wirén et al 1993).…”
Section: Metallophores and The Geochemistry Of Metal Bioavailabilitymentioning
confidence: 99%
“…Metallophores can be degraded, either microbially (Pierwola et al 2004;Villavicencio and Neilands 1965;Zaya et al 1998) or chemically via photochemical or heterogeneous redox reactions Duckworth and Sposito 2005a;Parker et al 2007). The dominant degradation mechanisms and rates under natural conditions for most metallophores are unknown, but degradation rates presumably depend on a combination of environmental factors, including the size and composition of the microbial community (von Wirén et al 1993).…”
Section: Metallophores and The Geochemistry Of Metal Bioavailabilitymentioning
confidence: 99%
“…A pseudomonad, isolated from soil and tentatively designed Pseudomonas FC1, is capable of degrading ferrichrome, ferrichrome A and coprogen (Warren and Neilands 1964). Azospirillum irakense and Mesorhizobium loti were shown to catabolise desferrioxamine B and other linear and cyclic desferrioxamines (Winkelmann et al 1999;Pierwola et al 2004). In all three cases the degradation of the siderophores is concomitant with growth of the soil isolates and ascribed to cellular enzymes like proteinases or peptidases.…”
Section: Resultsmentioning
confidence: 96%
“…3) and desferri-ferrichrome were not degraded, indicating a high substrate specificity of the desferrioxamine hydrolase (Winkelmann et al 1999). Similarly, Mesorhizobium loti can grow and reproduce in a medium containing DFOB as the sole carbon source, and the dissimilation of DFOB generates monohydroxamic acids, most likely following a specific degradation pathway representing the reversal of the biosynthesis pathway (Pierwola et al 2004). In the case of all three of the aforementioned soil bacteria species, siderophore degradation is ascribed to cellular enzymes, like proteases and hydrolases (Zaya et al 1998).…”
Section: Microbial Degradation Of Siderophoresmentioning
confidence: 98%