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Inhibiting the BfrB:Bfd interaction in Pseudomonas aeruginosa causes irreversible iron accumulation in bacterioferritin and iron deficiency in the bacterial cytosol. | LitMetric

Inhibiting the BfrB:Bfd interaction in Pseudomonas aeruginosa causes irreversible iron accumulation in bacterioferritin and iron deficiency in the bacterial cytosol.

Metallomics

Department of Chemistry and R. N. Adams Institute for Bioanalytical Chemistry, University of Kansas, Multidisciplinary Research Building, 2030 Becker Dr, Lawrence, KS 66047, USA.

Published: June 2017

AI Article Synopsis

  • Iron is vital for bacterial growth, but its reactivity and insolubility make it difficult for bacteria to manage; iron storage proteins like ferritins and bacterioferritins help mitigate these challenges by storing and oxidizing iron.* -
  • In P. aeruginosa, two iron storage proteins (FtnA and BfrB) coexist, but their specific roles in maintaining iron balance are unclear; prior research suggests that the interaction between BfrB and ferredoxin (Bfd) is crucial for iron mobilization.* -
  • The study investigates the effects of deleting the bfrB gene and altering the BfrB:Bfd interaction, finding that BfrB is primarily responsible for iron accumulation, and

Article Abstract

Iron is an essential nutrient for bacteria but the reactivity of Fe and the insolubility of Fe present significant challenges to bacterial cells. Iron storage proteins contribute to ameliorating these challenges by oxidizing Fe using O and HO as electron acceptors, and by compartmentalizing Fe. Two types of iron-storage proteins coexist in bacteria, the ferritins (Ftn) and the heme-containing bacterioferritins (Bfr), but the reasons for their coexistence are largely unknown. P. aeruginosa cells harbor two iron storage proteins (FtnA and BfrB), but nothing is known about their relative contributions to iron homeostasis. Prior studies in vitro have shown that iron mobilization from BfrB requires specific interactions with a ferredoxin (Bfd), but the relevance of the BfrB:Bfd interaction to iron homeostasis in P. aeruginosa is unknown. In this work we explore the repercussions of (i) deleting the bfrB gene, and (ii) perturbing the BfrB:Bfd interaction in P. aeruginosa cells by either deleting the bfd gene or by replacing the wild type bfrB gene with a L68A/E81A double mutant allele in the P. aeruginosa chromosome. The effects of the mutations were evaluated by following the accumulation of iron in BfrB, analyzing levels of free and total intracellular iron, and by characterizing the ensuing iron homeostasis dysregulation phenotypes. The results reveal that P. aeruginosa accumulates iron mainly in BfrB, and that the nutrient does not accumulate in FtnA to detectable levels, even after deletion of the bfrB gene. Perturbing the BfrB:Bfd interaction causes irreversible flow of iron into BfrB, which leads to the accumulation of unusable intracellular iron while severely depleting the levels of free intracellular iron, which drives the cells to an acute iron starvation response despite harboring "normal" levels of total intracellular iron. These results are discussed in the context of a dynamic equilibrium between free cytosolic Fe and Fe compartmentalized in BfrB, which functions as a buffer to oppose rapid changes of free cytosolic iron. Finally, we also show that P. aeruginosa cells utilize iron stored in BfrB for growth in iron-limiting conditions, and that the utilization of BfrB-iron requires a functional BfrB:Bfd interaction.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5494978PMC
http://dx.doi.org/10.1039/c7mt00042aDOI Listing

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