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Atherosclerosis is accepted to be a chronic inflammatory disease of the arterial vessel wall. Several cellular subsets of the immune system are involved in its initiation and progression, such as monocytes, macrophages, T and B cells. Recent research has demonstrated that dendritic cells (DCs) contribute to atherosclerosis, too. DCs are defined by their ability to sense and phagocyte antigens, to migrate and to prime other immune cells, such as T cells. Although all DCs share these functional characteristics, they are heterogeneous with respect to phenotype and origin. Several markers have been used to describe DCs in different lymphoid and non-lymphoid organs; however, none of them has proven to be unambiguous. The expression of surface molecules is highly variable depending on the state of activation and the surrounding tissue. Furthermore, DCs in the aorta or the atherosclerotic plaque can be derived from designated precursor cells or from monocytes. In addition, DCs share both their marker expression and their functional characteristics with other myeloid cells like monocytes and macrophages. The repertoire of aortic DCs in healthy and atherosclerotic mice has just recently started to be explored, but yet there is no systemic study available, which describes the aortic DC compartment. Because it is conceivable that distinct aortic DC subsets exert dedicated functions, a detailed description of vascular DCs is required. The first part of this thesis characterizes DC subsets in healthy and atherosclerotic mice. It describes a previously unrecognized DC subset and also sheds light on the origin of vascular DCs. In recent years, microRNAs (miRNAs) have been demonstrated to regulate several cellular functions, such as apoptosis, differentiation, development or proliferation. Although several cell types have been characterized extensively with regard to the miRNAs involved in their regulation, only few studies are available that focus on the role of miRNAs in DCs. Because an improved understanding of the regulation of DC functions would allow for new therapeutic options, research on miRNAs in DCs is required. The second part of this thesis focuses on the role of the miRNA cluster miR- 17~92 in DCs by exploring its functions in healthy and atherosclerotic mice. This thesis clearly demonstrates for the first time an anti-inflammatory and atheroprotective role for the miR17-92 cluster. A model for its mechanism is suggested.
According to the hygiene hypothesis, the exposure to infectious agents in early childhood prevents the development of allergen-specific Th2 immune responses because it establishes Th1-based immunity or alternatively, induces the generation of T regulatory cells. Based on this theory, the present study pretended to identify promising microorganism-derived vaccine candidates against allergic asthma in the murine model. In the first part of this work, the efficacy of four different known Th1-inducing adjuvants, i.e. live BCG, heat-killed BCG, CpG and PPD, as components of vaccines aimed at inhibiting allergic asthma was compared. All the adjuvants were effective in inhibiting the development of allergen-induced airway eosinophilia, mucus production, and with the exception of PPD also airway hyperreactivity (AHR), when they were applied together with OVA/alum. Suppression of airway eosinophilia was not observed in IFN-gamma- or IL-12-deficient mice (hk-BCG, CpG-ODN and PPD). Interestingly, live BCG was still able to suppress allergen-induced Th2 responses in the absence of either IFN-gamma or IL-12. The effect of live BCG was also independent on IL-10-, TLR-2-, TLR-4- or MyD88-mediated signaling. When mice vaccinated with the different adjuvants together with OVA/alum were subjected to a second period of OVA/alum immunization, only live and hk-BCG were able to efficiently suppress the development of airway inflammation. This effect could be adoptively transferred by CD4+ T cells. Taken together our data suggest that live BCG>>hk-BCG>CpG>PPD are effective in suppressing allergen-induced Th2 responses. Secondly, the evaluation of a dendritic cell-based vaccination strategy leading to the induction of allergen-specific Th1 cells to protect against the development of allergen-specific Th2 responses was performed. The application of OVA-pulsed BM-DC maturated with CpG was unable to reduce airway eosinophilia and inflammation in OVA-immunized mice. OVA-specific IgG1 or IgE serum levels were also not reduced. The experiments using LC pulsed with OVA yielded similar results. However, the mice vaccinated with CpG/OVA pulsed BM-DC had greatly enhanced levels of OVA-specific IgG2a in the serum, suggesting the induction of allergen-specific Th1 responses in vivo. Thus, these data suggest that the vaccination of mice with OVA-pulsed BM-DC matured with CpG or OVA-pulsed LC did not result in a reduction of allergen-specific Th2 responses in a murine model of severe atopic asthma. Lastly, NES, an excretory/secretory product derived from the helminth Nippostrongylus brasiliensis was evaluated as a new potential adjuvant to prevent the development of allergic responses. The application of NES together with OVA/alum greatly inhibited the development of airway eosinophilia, airway goblet cell metaplasia and mucus production and the development of airway hyperreactivity after metacholine challenge. Furthermore, OVA-specific IgG1 and IgE levels in the serum were also strongly reduced. NES preparations contained small amounts of endotoxin, which may explain these results. However, the suppressive effects of NES on the development of allergen-specific Th2 responses was independent upon IFN-gamma or TLR-4 and still observed in mice treated with LPS-depleted NES. NES reduced OVA-induced Th2 responses also in a IL-10-independent manner. In addition, the digestion with proteinase K or the heat-treatment of NES did not abolish its ability to inhibit allergen-induced Th2 responses. Interestingly, NES suppress OVA-specific Th2 responses in vivo in the presence of a strong NES-specific Th2 environment. Taken together our results suggest that the helminth N. brasiliensis secretes substances which interfere with the development of allergic Th2 responses. In summary, distinct substances derived from microorganisms or helminths which may be used as potential adjuvants to prevent the development of allergic Th2 responses were identified. These findings contribute to the design of efficient vaccines protecting humans from developing allergic asthma.