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In vivo growth of Staphylococcus lugdunensis is facilitated by the concerted function of heme and non-heme iron acquisition mechanisms

Ronald S. Flannagan, Jeremy R. Brozyna, Brijesh Kumar, Lea Antje Adolf, Jeffrey J. Power, Simon Heilbronner, David E. Heinrichs

2022Journal of Biological Chemistry25 citationsDOIOpen Access PDF

Abstract

Staphylococcus lugdunensis has increasingly been recognized as a pathogen that can cause serious infection indicating this bacterium overcomes host nutritional immunity. Despite this, there exists a significant knowledge gap regarding the iron acquisition mechanisms employed by S. lugdunensis, especially during infection of the mammalian host. Here we show that S. lugdunensis can usurp hydroxamate siderophores and staphyloferrin A and B from Staphylococcus aureus. These transport activities all required a functional FhuC ATPase. Moreover, we show that the acquisition of catechol siderophores and catecholamine stress hormones by S. lugdunensis required the presence of the sst-1 transporter-encoding locus, but not the sst-2 locus. Iron-dependent growth in acidic culture conditions necessitated the ferrous iron transport system encoded by feoAB. Heme iron was acquired via expression of the iron-regulated surface determinant (isd) locus. During systemic infection of mice, we demonstrated that while S. lugdunensis does not cause overt illness, it does colonize and proliferate to high numbers in the kidneys. By combining mutations in the various iron acquisition loci (isd, fhuC, sst-1, and feo), we demonstrate that only a strain deficient for all of these systems was attenuated in its ability to proliferate to high numbers in the murine kidney. We propose the concerted action of heme and non-heme iron acquisition systems also enable S. lugdunensis to cause human infection.

Topics & Concepts

Staphylococcus lugdunensisHemeIn vivoChemistryFunction (biology)HemeproteinBiochemistryMicrobiologyStaphylococcusStaphylococcus aureusBiologyCell biologyBacteriaGeneticsEnzymeClostridium difficile and Clostridium perfringens researchBacterial biofilms and quorum sensingPorphyrin Metabolism and Disorders