Abstract
Iron acquisition through siderophores, a class of small, potent iron-chelating organic molecules, is a widely spread strategy among pathogens to survive in the iron-restricted environment found in the host. Although these molecules have been implicated in the pathogenesis of several species, there is currently no comprehensive study addressing siderophore production in Staphylococcus epidermidis. Staphylococcus epidermidis is an innocuous skin commensal bacterium. The species, though, has emerged as a leading cause of implant-associated infections, significantly supported by an inherent ability to form biofilms. The process of adaptation from skin niche environments to the hostile conditions during invasion is yet not fully understood. Herein, we addressed the possible role of siderophore production in S. epidermidis virulence. We first identified and deleted a siderophore homolog locus, sfaABCD, and provided evidence for its involvement in iron acquisition. Our findings further suggested the involvement of siderophores in the protection against oxidative stress-induced damage and demonstrated the in vivo relevance of a siderophore-mediated iron acquisition during S. epidermidis infections. Conclusively, this study addressed, for the first time in this species, the underlying mechanisms of siderophore production, highlighting the importance of a siderophore-mediated iron acquisition under host relevant conditions and, most importantly, its contribution to survival within the host.
Highlights
Iron, one of the most abundant metals on Earth, is a key nutrient for almost all living organisms, including bacteria [1]
This observation, along with results obtained in S. aureus [28], led us to hypothesize that this gene cluster is involved in siderophore biosynthesis in S. epidermidis
Wt and sfa strains were cultured under iron-deficient conditions {iron-restricted chemically defined medium [CDM(Fe–)]; iron content
Summary
One of the most abundant metals on Earth, is a key nutrient for almost all living organisms, including bacteria [1]. Iron is not readily accessible to invading pathogens, either because it forms insoluble ferric hydroxide complexes under aerobic neutral pH conditions or because it is mostly bound to host-derived proteins (e.g., transferrin and ferritin) [2, 3]. This represents an effective host defense mechanism against microbial infections, which is commonly referred to as nutritional immunity [4]. Afterwards, siderophore-iron complexes are internalized by bacteria through dedicated uptake systems [10]
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