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The mold Aspergillus fumigatus (A. fumigatus) is known as human pathogen and can cause life-threatening infections in humans with a weakened immune system. This is a known complication in patients receiving glucocorticoids, e.g. after hematopoietic stem cell transplantation or solid organ transplantation. Although research in the field of immune cell/fungus interaction has discovered key strategies how immune cells fight against infectious fungi, our knowledge is still incomplete. In order to develop effective treatment options against fungal infections, a detailed understanding of their interactions is crucial. Thus, visualization of immune cell and fungus is an excellent approach to gain further knowledge. For a detailed view of such interaction processes, a high optical resolution on nanometer scale is required. There is a variety of super resolution microscopy techniques, enabling fluorescence imaging beyond the diffraction limit. This work combines the use of three complementary super resolution microscopy techniques, in order to study immune cell/fungus interaction from different points of view.
Aim of this work is the introduction of the recently invented imaging technique named expansion microscopy (ExM) for the study of immune cell/fungus interactions. The core aspect of this method is the physical magnification of the specimen, which increases the distance between protein structures that are close to each other and which can therefore be imaged separately.
The simultaneous magnification of primary human natural killer (NK) cells and A. fumigatus hyphae was established in this work using ExM. Reorganization of cytoskeletal components of interacting NK cells was demonstrated here, by expansion of the immunological synapse (IS), formed between NK cells and A. fumigatus. In addition, reorganization of the microtubule-organizing center (MTOC) towards fungal hyphae and an accumulation of actin at the IS has been observed. Furthermore, ExM has been used to visualize lytic granules of NK cells after degranulation. After magnification of the specimen, lysosome associated protein 1 (LAMP1) was shown to surround perforin. In absence of the plasma membrane-exposed degranulation marker LAMP1, a “ring-shaped” structure was often observed for fluorescently labeled perforin. Volume calculation of lytic granules demonstrated the benefit of ExM. Compared to pre-expansion images, analyses of post-expansion images showed two volume distributions for degranulated and non-degranulated NK cells. In addition, this work emphasizes the importance of determining the expansion factor for a structure in each species, as variations of expansion factors have been observed. This factor, as well as possible sample distortions should be considered, when ExM is used in order to analyze the interaction between two species.
A second focus of this work is the visualization of a chimeric antigen receptor (CAR), targeting an epitope on the cell wall of A. fumigatus. Structured illumination microscopy (SIM) revealed that the CAR is part of the immunological synapse of primary human CAR T cells and CAR-NK-92 cells. At the interaction site, an accumulation of the CAR was observed, as well as the presence of perforin. CAR accumulation at fungal hyphae was further demonstrated by automated live cell imaging of interacting CAR-NK-92 cells, expressing a fluorescent fusion protein.
Additionally, the use of direct stochastic optical reconstruction microscopy (dSTORM) gave first insights in CAR expression levels on the basal membrane of CAR-NK-92 cells, with single molecule sensitivity. CAR cluster analyses displayed a heterogeneous CAR density on the basal membrane of transfected NK 92 cells.
In summary, this work provides insights into the application of ExM for studying the interaction of primary human NK cells and A. fumigatus for the first time. Furthermore, this thesis presents first insights regarding the characterization of an A. fumigatus-targeting CAR, by applying super-resolution fluorescence microscopy, like SIM and dSTORM.
Bereits in Vorstudien konnte dargelegt werden, dass eine signifikante Korrelation zwischen der T-Zell-Zytokin-Antwort und der berufs- bzw. umweltbedingten Schimmelpilzbelastung besteht. Ziel der vorliegenden Studie war, eine mögliche Kombination von Biomarkern ausfindig zu machen, die veränderte T-Zell-Antworten auf A. fumigatus- Antigene bei beruflich Exponierten im Vergleich zu Kontrollprobanden/-innen vorhersagen kann. Um geeignete Marker für das Bio-Monitoring zu finden, wurden zur T-Zell-Aktivierung ein myzeliales A. fumigatus - Lysat und 12 proteinogene Antigene in ELISpot-Versuchen für die Signaturzytokine IFN-γ (TH1), IL-5 (TH2) und IL-17A (TH17) der Haupt-TH-Subpopulationen getestet.
Es zeigten sich bei den Biolandwirten/-innen erwartungsgemäß erhöhte TH1- und TH2-Antworten auf die Mehrzahl der verwendeten spezifischen A. fumigatus-Antigene, die möglicherweise eine Schimmelpilzbelastung serologisch nachweisbar machen. Insbesondere die spezifischen A. fumigatus-Antigene Aspf22, CatB und CipC konnten eine Trennschärfe zwischen den beiden Kohorten hinsichtlich ihrer IFN-γ- und IL-5-Zytokinantwort erzielen. Unterschiede in der TH17-Antwort aufgrund chronischer beruflicher Sporenbelastung ohne Krankheitskorrelat konnten nicht explizit festgestellt werden. Weiterhin ergab sich, dass erhöhte TH2-Immunreaktionen, sofern sie mit einer adäquaten TH1-gerichteten Immunantwort einhergehen und damit eine ausgeglichene TH2/TH1-Balance besteht, nicht zwangsläufig zu Hypersensitivitätserkrankungen führen. Im Vergleich zu Langzeitexponierten wurden teilweise überlappende TH-Zellfrequenzen bei beruflich exponierten Biolandwirten/-innen ermittelt. Welche entscheidende Rolle Treg-Zellen bei der Eindämmung überschießender Immunantworten einnehmen, kann hieraus erahnt werden.