Charles D. Cox

Ferric uptake regulator mutants of Pseudomonas aeruginosa with distinct alterations in the iron‐dependent repression of exotoxin A and siderophores in aerobic and microaerobic environments

Because the ferric uptake regulator (fur ) appears to be an essential gene in Pseudomonas aeruginosa, resistance to manganese was used as an enrichment to isolate strains carrying point mutations in the fur gene in order to assess its role in the co‐ordinate expression of siderophores and exotoxin A (ETA). This report describes a detailed molecular and phenotypic characterization of four mutants and one revertant, which carry point mutations in the fur gene. Two parental strains were used in this study. Three mutants were isolated from the widely used strain, PAO1. One of these, CS (cold sensitive), has a mutation in the 5′ non‐coding region of the fur gene while the two other mutants derived from this parent have mutations resulting in the following deduced changes in Fur: mutant A2, H86 → R; mutant A4, H86 → Y. The other mutant (C6) and its revertant (C6Rv) were derived from PAO6261, a mutant of PAO1 with a deletion in the anr gene (anaerobic regulation of arginine deiminase and nitrate reduction) that controls anaerobic respiration in P. aeruginosa. Fur from the C6 mutant has an A10 → G mutation while in the C6Rv spontaneous revertant the mutant Gly residue has been changed to Ser at this position. All mutants were examined for alterations in the iron‐regulated expression of siderophores and ETA. The A2 and A4 mutants expressed higher levels of siderophores in iron‐deficient media and in iron‐replete media. The CS mutant constitutively expressed siderophores at 25°C. At 42°C siderophore biosynthesis was iron repressed as in the parental strain PAO1. The deletion of anr in PAO6261 had no apparent effect on the iron‐mediated regulation of siderophore synthesis, but the C6 mutant derived from this strain produces siderophores constitutively. The iron‐regulated production of siderophores by C6Rv was similar to the parental strain PAO6261 and PAO1. Because one of the parental strains used in this study is an Anr mutant, regulation of ETA production was assessed under aerobic and microaerobic conditions. Iron‐dependent repression of ETA synthesis in both parental strains and A2 and A4 mutants was found to be 50–100‐fold under aerobic and microaerobic conditions, as assayed by quantitative Western dot‐blot assays. By contrast in the CS and C6 mutants, while iron‐dependent repression of ETA synthesis was similar to both parental strains under aerobic conditions, ETA production in these mutants was constitutive in a microaerobic environment. RNase protection analysis of toxA and regAB transcription in PAO1, PAO6261 and the C6 mutant corroborated the results of quantitative dot‐blot assays of ETA. The mutant Fur proteins were purified and examined for their ability to bind to the promoter of a gene (pvdS ) that positively regulates the expression of siderophores and ETA. Fur from the A2 and A4 mutants and from the C6Rv revertant was able to bind to the target DNA, but with reduced affinity by comparison to wild‐type Fur. Fur from the C6 mutant in DNase I footprint experiments failed to protect the promoter region of the pvdS gene, but it retained some weak binding activity in gel mobility shift assays. The data presented in this study not only furnish some additional insights into the structure–function relationships of Fur, but also afford novel perspectives with regard to Fur and the iron‐dependent regulation of virulence factors in P. aeruginosa under environmental conditions that have not previously been considered.

Interaction of the Pseudomonas aeruginosa secretory products pyocyanin and pyochelin generates hydroxyl radical and causes synergistic damage to endothelial cells. Implications for Pseudomonas-associated tissue injury.

Pyocyanin, a secretory product of Pseudomonas aeruginosa, has the capacity to undergo redox cycling under aerobic conditions with resulting generation of superoxide and hydrogen peroxide. By using spin trapping techniques in conjunction with electron paramagnetic resonance spectrometry (EPR), superoxide was detected during the aerobic reduction of pyocyanin by NADH or porcine endothelial cells. No evidence of hydroxyl radical formation was detected. Chromium oxalate eliminated the EPR spectrum of the superoxide-derived spin adduct resulting from endothelial cell exposure to pyocyanin, suggesting superoxide formation close to the endothelial cell plasma membrane. We have previously reported that iron bound to the P. aeruginosa siderophore pyochelin (ferripyochelin) catalyzes the formation of hydroxyl free radical from superoxide and hydrogen peroxide via the Haber-Weiss reaction. In the present study, spin trap evidence of hydroxyl radical formation was detected when NADH and pyocyanin were allowed to react in the presence of ferripyochelin. Similarly, endothelial cell exposure to pyocyanin and ferripyochelin also resulted in hydroxyl radical production which appeared to occur in close proximity to the cell surface. As assessed by 51Cr release, endothelial cells which were treated with pyocyanin or ferripyochelin alone demonstrated minimal injury. However, endothelial cell exposure to the combination of pyochelin and pyocyanin resulted in 55% specific 51Cr release. Injury was not observed with the substitution of iron-free pyochelin and was diminished by the presence of catalase or dimethyl thiourea. These data suggest the possibility that the P. aeruginosa secretory products pyocyanin and pyochelin may act synergistically via the generation of hydroxyl radical to damage local tissues at sites of pseudomonas infection.

Pseudomonas pyocyanine alters calcium signaling in human airway epithelial cells

Pseudomonas aeruginosa, an opportunistic human pathogen, causes both acute and chronic lung disease. P. aeruginosa exerts many of its pathophysiological effects by secreting virulence factors, including pyocyanine, a redox-active compound that increases intracellular oxidant stress. Because oxidant stress has been shown to affect cytosolic Ca2+ concentration ([Ca2+]c) in other cell types, we studied the effect of pyocyanine on [Ca2+]cin human airway epithelial cells (A549 and HBE). At lower concentrations, pyocyanine inhibits inositol 1,4,5-trisphosphate formation and [Ca2+]cincreases in response to G protein-coupled receptor agonists. Conversely, at higher concentrations, pyocyanine itself increases [Ca2+]c. The pyocyanine-dependent [Ca2+]cincrease appears to be oxidant dependent and to result from increased inositol trisphosphate and release of Ca2+ from intracellular stores. Ca2+ plays a central role in epithelial cell function, including regulation of ion transport, mucus secretion, and ciliary beat frequency. By disrupting Ca2+ homeostasis, pyocyanine could interfere with these critical functions and contribute to the pathophysiological effects observed in Pseudomonas-associated lung disease.

Iron Acquisition from Pseudomonas aeruginosa Siderophores by Human Phagocytes: an Additional Mechanism of Host Defense through Iron Sequestration?

ABSTRACT Chelation of iron to iron-binding proteins is a strategy of host defense. Some pathogens counter this via the secretion of low-molecular-weight iron-chelating agents (siderophores). Human phagocytes possess a high-capacity mechanism for iron acquisition from low-molecular-weight iron chelates. Efficient acquisition and sequestration of iron bound to bacterial siderophores by host phagocytes could provide a secondary mechanism to limit microbial access to iron. In the present work we report that human neutrophils, macrophages, and myeloid cell lines can acquire iron from the twoPseudomonas aeruginosa siderophores. Analogous to iron acquisition from other low-molecular-weight chelates, iron acquisition from the siderophores is ATP independent, induced by multivalent cationic metals, and unaffected by inhibitors of endocytosis and pinocytosis. In vivo, this process could serve as an additional mechanism of host defense to limit iron availability to invading siderophore-producing microbes.