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Staphylococcus aureus is a pathogenic bacterium infecting the human host. It’s multifaced adaptation to various environmental conditions is mediated by a tight regulation of the virulence factors influencing the host’s immune system. In this thesis two regulators of gene expression were analysed: (i) the global influence of the two-component system SaePQRS and (ii) the regulation of superantigen gene expression by the alternative sigma factor σB. At the outset of this thesis, single target genes induced by SaeRS were known (hla, hlb, cap5, fnbA, coa). In order to get a general idea of the Sae-regulon, the influence of SaePQRS on gene-expression was analysed in two strain backgrounds by proteomics and transcriptomics aproaches. Recapitulatory, expression of at least 18 secreted and two covalently cell-wall bound proteins was decreased following inactivation of the Sae-system. Sae-dependently expressed were, amongst others, well decribed virulence factors like the y-hemolysins HlgA, HlgB, HlgC, LukM and LukF, the innate immune system modulating proteins Efb, CHIPS and SCIN-B as well as the enterotoxin SEB. SaeR acts as an activator of its target genes. Some proteins were detected in increased amounts in the extracellular proteome of the Sae-deficient strain. However, these changes did not occur at the transcriptional level. The expression of virulence factors is determined by other global regulators. No influence of SaePQRS on the transcription of five substancial regulators, namely the Agr-system and its effector molecule RNAIII, the alternative sigma factor σB, the two-component system ArlRS and the DNA-binding protein SarA, could be shown. In the second part of this thesis the issue was broached to the regulation of gene-expression of a subgroup of virulence factors, the superantigens (SAgs) of S. aureus by SaePQRS and σB. In contrast to their well described molecule structure and function, the regulation of their gene expression was largely unknown. Six different S. aureus strains (two laboratory strains and four clinical isolates) encoding one to seven SAg-genes each, were used for analysis of a total of twelve SAgs regarding their transcription and mitogenic activity. The transcriptional units were characterized using Northern-Blotting. The expression of SAgs could be correlated to the respective growth phase. While egc-SAgs were expressed mainly at low optical densities, seb was induced during late growth phase. In contrast, the transcription of sea, seh, sek, tst and sep remained constant and growth-phase independent. The transcriptional dataset was verified using T-cell proliferation assays. The expression of seh, tst and the egc-operon was dependent on σB. A potential σB-dependent promotor could be identified preceeding seo, the first gene of the egc-operon. In contrast, the expression of seb was increased in sigB-deficient background. This might be due to indirect effects. Expression of seb required SaePQRS. Transcriptional datasets were verified by Immuno-Blotting and T-cell-proliferation assays. In conclusion, the same mutation in sigB but in different strain backgrounds could result in opposite phenotypes with respect to their mitogenic activity. Besides well characterized virulence factors, some secreted proteins with so far unknown function belong to the Sae-regulon. Given that the influence of SaePQRS was restricted to virulence factors and induced especially modulators of the innate immune system, it can be assumed, that these proteins potentially play a role in virulence of S. aureus. In the third part of this thesis, one of these potential new virulence factors, namely SACOL0908, was analysed in detail. In cooperation with the group of Prof. Stehle, Tübingen, the crystal structure was solved. The protein folding of SACOL0908 is new with only minor similarities to described protein structures. Recombinantly expressed SACOL0908 binds to granulocytes. These cells belong to the innate immune system, incorporate bacteria by phagocytosis and kill them. The receptor for SACOL0908 on the surface of granulocytes could not be identified using immunoprecipitation, antibody-blocking assays and functional assays in cooperation with the group of Prof. Peschel, Tübingen. The gene encoding SACOL0908 was deleted in two S. aureus strain backgrounds (COL and Newman). These mutants are currently in use to characterize their phenotype in mouse-infection studies.
This thesis contains results from transcriptome studies on different aspects of host-pathogen interactions. First, liver gene expression profiles from a murine chronic stress model served to elucidate aspects of the influence of stress on metabolism and immune response state. Chronic stress in female BALB/c mice was shown to lead to a hypermetabolic syndrome including induction of gluconeogenesis, hypercholesteremia, and loss of essential amino acids, to the induction of the acute phase response, but also of immune suppressive pathways and to the repression of hepatic antigen presentation. Increased leukocyte trafficking, increased oxidative stress together with counter-regulatory gene expression changes, and an induction of apoptosis were detected. The influence of intra-venous infection on the host kidney gene expression was analyzed in another murine model using the wild type strain Staphylococcus aureus RN1HG and its isogenic sigB mutant. Gene expression profiling indicated a highly reproducible host kidney response to infection. The comparison of infected with non-infected samples revealed a strong inflammatory reaction of kidney tissue, e. g. Toll-like receptor signaling, complement system, antigen presentation, interferon and IL-6 signaling. However, the results of this study did not provide any hints for differences in the pathomechanism of the S. aureus strains RN1HG and ΔsigB, since the host response did not differ between infections with the two strains analyzed. Effects of SigB might be transient, only apparent at earlier time points, or might also be compensated for in the in vivo infection by the interlaced pattern of other regulators. SigB might possess only to a lesser extent characteristics attributed to virulence factors and might act in vivo more like a virulence modulator and fine tune bacterial reactions. In addition to the analysis of tissue samples, different in vitro models were furthermore studied. The third part of this thesis focuses on bone-marrow derived macrophages (BMM) of the two mouse strains BALB/c and C57BL/6, which are described in literature to exhibit genetically determined differences in their reaction to infection. Expression profiling was performed on control and IFN-γ treated samples from a serum-free cultivation system and revealed mainly induction of gene expression after treatment of BMM with IFN-γ. Gene expression changes confirmed known IFN-γ effects like induction of immunoproteasome, antigen presentation, interferon signaling related genes, GTPase/GBPs, and inducible NO synthase. IFN-γ dependent gene expression changes were highly similar in BALB/c and C57BL/6 BMM. Considering gene expression differences between BMM of both strains, a similar expression trend was visible on the level of untreated controls as well as after IFN-γ treatment. Differentially expressed genes between BMM of both strains included immune-relevant genes as well as genes linked to cell death, but the coverage of functional groups was limited. The bronchial epithelial cell line S9 was used as an in vitro model system for the infection with S. aureus RN1HG. The fourth chapter in this thesis includes S9 cell gene expression signatures 2.5 h and 6.5 h after start of infection. At the early time point, only 40 genes were differentially expressed, which nevertheless indicated a beginning pro-inflammatory response, e. g. induction of cytokines (IL-6, IFN-β, LIF) or prostaglandin-endoperoxide synthase 2 (PTGS2), but also counter-regulatory processes, e. g. induction of CD274. The host cell response was dramatically aggravated at the later 6.5 h time point. Differential expression was detected for 1196 genes. These included induced cytokines, pattern recognition receptor signaling, antigen presentation, and genes involved in immune defense (e. g. GBPs, MX, APOL). Negative effects on growth and proliferation were even more enhanced in comparison to the early time point, and signs for apoptotic processes were revealed. Finally, the last chapter addresses amongst others the pathogen’s expression profile in the S9 cell in vitro infection model at the two time points 2.5 h and 6.5 h after start of infection by tiling array gene expression analysis. The pathogen expression profiling revealed the activity of the SaeRS two-component system in internalized staphylococci. Partly dependent on SaeRS, the induction of adhesins (e. g. fnbAB, clfAB), toxins (hlgBC, lukDE, hla), and immune evasion genes (e. g. chp, eap) was observed. Furthermore, expression changes of metabolic genes were recorded (gene induction of amino acid biosynthesis, TCA cycle, gluconeogenesis; gene repression of glycolysis, purine biosynthesis, tRNA synthetases). Expression analysis recorded a distinct bacterial expression program, which supported literature results of a specific, bacterial strain and host cell line dependent transcriptional adaptation of the pathogen.