Abstract
S. epidermidis is a substantial component of the human skin microbiota, but also one of the major causes of nosocomial infection in the context of implanted medical devices. We here aimed to advance the understanding of S. epidermidis genotypes and phenotypes conducive to infection establishment. Furthermore, we investigate the adaptation of individual clonal lines to the infection lifestyle based on the detailed analysis of individual S. epidermidis populations of 23 patients suffering from prosthetic joint infection. Analysis of invasive and colonizing S. epidermidis provided evidence that invasive S. epidermidis are characterized by infection-supporting phenotypes (e.g. increased biofilm formation, growth in nutrient poor media and antibiotic resistance), as well as specific genetic traits. The discriminating gene loci were almost exclusively assigned to the mobilome. Here, in addition to IS256 and SCCmec, chromosomally integrated phages was identified for the first time. These phenotypic and genotypic features were more likely present in isolates belonging to sequence type (ST) 2. By comparing seven patient-matched nasal and invasive S. epidermidis isolates belonging to identical genetic lineages, infection-associated phenotypic and genotypic changes were documented. Besides increased biofilm production, the invasive isolates were characterized by better growth in nutrient-poor media and reduced hemolysis. By examining several colonies grown in parallel from each infection, evidence for genetic within-host population heterogeneity was obtained. Importantly, subpopulations carrying IS insertions in agrC, mutations in the acetate kinase (AckA) and deletions in the SCCmec element emerged in several infections. In summary, these results shed light on the multifactorial processes of infection adaptation and demonstrate how S. epidermidis is able to flexibly repurpose and edit factors important for colonization to facilitate survival in hostile infection environments.
Highlights
Staphylococcus epidermidis is a major component of the human skin microbiota [1], but at the same time causes up to 30% of nosocomial bloodstream infections and over 30% of prosthetic joint infections (PJI), leading to high morbidity and gross excess health care costs[2,3,4,5]
The fact that S. epidermidis is able to colonize in a variety of conditions hints at its Invasive Staphylococcus epidermidis populations outstanding potential for adaptation which could benefit the pathogen in persisting in chronic infections [1]
Twenty-three patients with clinical signs of PJI were included into the study based on the recovery of S. epidermidis from at least one preoperatively collected joint fluid and from one intraoperative specimen
Summary
Staphylococcus epidermidis is a major component of the human skin microbiota [1], but at the same time causes up to 30% of nosocomial bloodstream infections and over 30% of prosthetic joint infections (PJI), leading to high morbidity and gross excess health care costs[2,3,4,5]. The success of S. epidermidis as a pathogen may not strictly depend on a defined subset of genes or a specific genetic background, but rather on the ability to flexibly adapt to challenging environmental conditions after translocation from the colonizing habitat to the site of infection. The fact that S. epidermidis is able to colonize in a variety of conditions hints at its Invasive Staphylococcus epidermidis populations outstanding potential for adaptation which could benefit the pathogen in persisting in chronic infections [1]. The basis of such adaptive processes are dynamic tuneable, regulatory networks [8,20,21]. In the related species Staphylococcus aureus differentiation into quorum-sensing-mediated bi-stable phenotypes through positive feedback loops depending on environmental cues has been described [24]
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