Typhi, can infect these mice and cause aspects of the pathology that is observed in human patients. However, with respect to the elicited human immune responses, more needs to be done to evaluate the immune competence of these models. While it has become clear thus far that isotype-switched humoral immune responses are difficult to achieve, cell-mediated T-cell immunity can be detected
in most of the investigated infections. In contrast to adaptive immune responses, Mitomycin C innate immunity is still largely unexplored in most of these infectious settings and remains an interesting and promising topic for examination. Therefore, further studies are required to characterize in detail the immune competence of human reconstituted innate leukocyte populations. Moreover, apart from the evaluation of genetically modified pathogens, which the field is starting to explore, genetic modifications by viral MG-132 nmr transduction of transferred hematopoietic progenitor cells have to be established. In addition, more information on the donor variability of reconstitution in relation to genetic polymorphisms needs to be gathered. Furthermore, a set of antibodies that not only deplete reconstituted human leukocyte populations, but instead block distinct receptors, needs to be established. Finally, treatments that robustly induce secondary lymphoid tissues
in mice with reconstituted human immune system components would be of great value. While several additional Nintedanib (BIBF 1120) methodological developments are needed to improve the versatility of in vivo models of human immune responses, combining these efforts with recent and ongoing studies of infection and immunity in vivo promises to result in new preclinical models that are more predictive than current models for immune reactivity and therapy in patients. Work in our laboratory is supported by the National Cancer Institute (R01CA108609), Sassella Foundation (10/02, 11/02, and 12/02), Cancer Research Switzerland (KFS-02652–08–2010), Association for International Cancer Research (11–0516), KFSPMS and KFSPHLD of the University of Zurich, Vontobel
Foundation, Baugarten Foundation, EMDO Foundation, Sobek Foundation, Fondation Acteria, Novartis, and Swiss National Science Foundation (310030_143979 and CRSII3_136241). The authors declare no financial or commercial conflict of interest. “
“Macrophages and polymorphonuclear neutrophils are professional phagocytes essential in the initial host response against intracellular pathogens such as Mycobacterium tuberculosis. Phagocytosis is the first step in phagocyte-pathogen interaction, where the pathogen is engulfed into a membrane-enclosed compartment termed a phagosome. Subsequent effector functions of phagocytes result in killing and degradation of the pathogen by promoting phagosome maturation, and, terminally, phago-lysosome fusion.