The Catabolism and Heterotrophic Nitrification of the Siderophore Deferrioxamine B

Overview

Journal Biol Met

Specialty Biology

Date 1990 Jan 1

PMID 2073460

Citations 4

Authors

D Castignetti

A S Siddiqui

Affiliations

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Abstract

Three bacteria, two of which were previously noted as active heterotrophic nitrifiers, were examined for their ability to grow and nitrify with the siderophore deferrioxamine B as the carbon source. Pseudomonas aureofaciens displayed limited growth and nitrification while a heterotrophic nitrifying Alcaligenes sp. was without action concerning its metabolism of deferrioxamine B. The third bacterium, a unique Gram-negative soil isolate, was unable to nitrify deferrioxamine B but grew well when the siderophore was employed as the sole C source. The Gram-negative bacterium removed deferrioxamine B from the medium and left only residual amounts of the compound in solution at the termination of its growth. The organism was without action when the ferrated analogue of deferrioxamine B, ferrioxamine B, served as either the C source for growth, for metabolism by resting cells, or as the substrate for cell-free extracts. Deferrioxamine B, by contrast, was rapidly metabolized by resting cells. Cell-free extracts of the bacterium synthesized a monohydroxamate(s) when deferrioxamine B was the substrate. The catabolism of deferrioxamine B, which is synthesized by soil microbes, suggests that soil microflora have the ability to return deferrioxamine B, and perhaps other, siderophores to the C cycle.

Citing Articles

Discovery of Peptidic Siderophore Degradation by Screening Natural Product Profiles in Marine-Derived Bacterial Mono- and Cocultures.

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Siderophore production by streptomycetes-stability and alteration of ferrihydroxamates in heavy metal-contaminated soil.

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PMID: 25414032 DOI: 10.1007/s11356-014-3842-3.

Degradation pathway and generation of monohydroxamic acids from the trihydroxamate siderophore deferrioxamine B.

Pierwola A, Krupinski T, Zalupski P, Chiarelli M, Castignetti D Appl Environ Microbiol. 2004; 70(2):831-6.

PMID: 14766561 PMC: 348822. DOI: 10.1128/AEM.70.2.831-836.2004.

Characterization of a novel Spirillum-like bacterium that degrades ferrioxamine-type siderophores.

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The nutritional selectivity of a siderophore-catabolizing bacterium.

DeAngelis R, Forsyth M, Castignetti D Biometals. 1993; 6(4):234-8.

PMID: 8260793 DOI: 10.1007/BF00187761.

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