Staphylococcus aureus is both a successful human commensal and a major pathogen. The elucidation of the molecular determinants of virulence, in particular assessment of the contributions of the genetic background versus those of mobile genetic elements (MGEs), has proved difficult in this variable species. To address this, we simultaneously determined the genetic backgrounds (spa typing) and the distributions of all 19 known superantigens and the exfoliative toxins A and D (multiplex PCR) as markers for MGEs. Methicillin-sensitive S. aureus strains from Pomerania, 107 nasal and 88 blood culture isolates, were investigated. All superantigenencoding MGEs were linked more or less tightly to the genetic background. Thus, each S. aureus clonal complex was characterized by a typical repertoire of superantigen and exfoliative toxin genes. However, within each S. aureus clonal complex and even within the same spa type, virulence gene profiles varied remarkably. Therefore, virulence genes of nasal and blood culture isolates were separately compared in each clonal complex. The results indicated a role in infection for the MGE harboring the exfoliative toxin D gene. In contrast, there was no association of superantigen genes with bloodstream invasion. In summary, we show here that the simultaneous assessment of virulence gene profiles and the genetic background increases the discriminatory power of genetic investigations into the mechanisms of S. aureus pathogenesis.
Plasma medicine is an interdisciplinary field and recent clinical studies showed benefits of topical plasma application to chronic wounds. Whereas most investigations have focused on plasma-skin cell interaction, immune cells are omnipresent in most tissues as well. They not only elicit specific immune responses but also regulate inflammation, which is central in healing and regeneration. Plasma generates short-lived radicals and species in the gas phase. Mechanisms of plasma-cell interactions are not fully understood but it is hypothesized that reactive oxygen and nitrogen species (RONS) mediate effects of plasma on cells. In this study human blood cells were investigated after cold atmospheric plasma treatment with regard to oxidation and viability. Plasma generates hydrogen peroxide (H2O2) and the responses were similar in cells treated with concentration-matched H2O2. Both treatments gave an equivalent reduction in viability and this was completely abrogated if catalase was added prior to plasma exposure. Further, five oxidation probes were utilized and fluorescence increase was observed in plasma-treated cells. Dye-dependent addition of catalase diminished most but not all of the probe fluorescence, assigning H2O2 a dominant but not exclusive role in cellular oxidation by plasma. Investigations for other species revealed generation of nitrite and formation of 3-nitrotyrosine but not 3-chlorotyrosine after plasma treatment indicating presence of RNS which may contribute to cellular redox changes observed. Together, these results will help to clarify how oxidative stress associates with physical plasma treatment in wound relevant cells.
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