New drugs for use as tuberculosis (TB) treatment are needed due to the constrains of classical antibiotics against TB and the rise of antibiotic-resistant strains, making TB a harder and harder... Show moreNew drugs for use as tuberculosis (TB) treatment are needed due to the constrains of classical antibiotics against TB and the rise of antibiotic-resistant strains, making TB a harder and harder disease to treat. This thesis is focused on using the in vivo whole animalzebrafish embryo model for TB to evaluate potential anti-TB host-directed therapeutics (HDTs) arising from in vitro screens. Although in vitro screens for HDTs using cellular models can be performed at high throughput, a limiting step is the validation in whole animal models and translation of results to clinical applications. Due to the complex infection dynamics of mycobacteria, the use of whole animal models is indispensable in research into TB and the zebrafish model has contributed key findings about host-pathogen dynamics during mycobacterial infection. One of the most promising host targets of HDTs is autophagy, which is recognized as an important host-protective pathway. Boosting autophagy levels using HDTs could be a way to overcome the pathogen’s autophagy evasion strategies and could therefore be a promising therapeutic route. For this thesis we took advantage of the possibilities of the zebrafish embryo model for TB and the zebrafish toolkit to study several autophagy-modulating HDTs as potential anti-TB drugs. Show less
The zebrafish has earned its place among animal models to study tuberculosis and other infections caused by pathogenic mycobacteria. This model host is especially useful to study the role of... Show moreThe zebrafish has earned its place among animal models to study tuberculosis and other infections caused by pathogenic mycobacteria. This model host is especially useful to study the role of granulomas, the inflammatory lesions characteristic of mycobacterial disease. The optically transparent zebrafish larvae provide a window on the initial stages of granuloma development in the context of innate immunity. Application of fluorescent dyes and transgenic markers enabled real-time visualization of how innate immune mechanisms, such as autophagy and inflammasomes, are activated in infected macrophages and how propagating calcium signals drive communication between macrophages during granuloma formation. A combination of imaging, genetic, and chemical approaches has revealed that the interplay between macrophages and mycobacteria is the main driver of tissue dissemination and granuloma development, while neutrophils have a protective function in early granulomas. Different chemokine signaling axes, conserved between humans and zebrafish, have been shown to recruit macrophages permissive to mycobacterial growth, control their microbicidal capacity, drive their spreading and aggregation, and mediate granuloma vascularization. Finally, zebrafish larvae are now exploited to explore cell death processes, emerging as crucial factors in granuloma expansion. In this review, we discuss recent advances in the understanding of mycobacterial pathogenesis contributed by zebrafish models. Show less
Mycobacterium tuberculosis, the agent of TB, is one of the deadliest human pathogens, infecting one third of the global population. Establishment of infection by mycobacteria relies on complex... Show moreMycobacterium tuberculosis, the agent of TB, is one of the deadliest human pathogens, infecting one third of the global population. Establishment of infection by mycobacteria relies on complex interactions with host innate immune cells, especially macrophages. Once engulfed by macrophages, mycobacteria “usurp” the host cell machineries to facilitate dissemination and to establish an intracellular niche for survival and replication. To investigate how mycobacteria force the immune cells to support infection, we explored the chemokine pathway, best known for its capability to induce cell migration. To dissect the interplay between immune cells and the pathogen, we modelled human TB using the zebrafish-Mycobacterium marinum natural host-pathogen pair, which is attractive for the excellent optical accessibility of the zebrafish larvae and the possibility to apply genetic tools to impair the chemokine signaling. We show that depletion of either CXCR3 or CXCR4 axes are beneficial to the host. Exploitation of CXCR3 signaling leads to macrophage recruitment and to transcriptional changes in macrophages that make them more permissive for mycobacterial intracellular persistence. Activating CXCR4 signaling triggers instead vascularization of the nascent tuberculous granulomas, which in turn supports expansion of the infection. Therefore, inhibitions of these pathways represent promising host-directed therapeutic avenues to counteract mycobacterial diseases. Show less
Type I immune responses play an essential role in the control of mycobacterial infections. Mutations in the genes involved in the type I cytokine pathway were found in patients with Mendelian... Show moreType I immune responses play an essential role in the control of mycobacterial infections. Mutations in the genes involved in the type I cytokine pathway were found in patients with Mendelian susceptibility to mycobacterial diseases. These patients are highly susceptible to infections with non-tuberculous mycobacteria (NTM), which are usually poorly pathogenic. The first part of this thesis focuses on the relation between the genotype and phenotype in the cause of an impaired immunity leading to the susceptibility to NTM infections. The role of genetic factors in the control of infections with more virulent tuberculous mycobacteria is less evident. The second part of this thesis focuses on putative non-genetic causes of an impaired immunity in the control of tuberculous mycobacterial diseases. In tuberculosis patients type I immune responses regulated by interferon-_ are also repressed. Virally induced interferons, other than interferon-_, may be involved in this repression, thereby influencing the immunopathogenesis of tuberculosis. Show less
