The research described in this thesis has, using the zebrafish as a model system, shed new light on the intricate relationship between TB and DM2, in particular on the role of leptin, SHP-1 and... Show moreThe research described in this thesis has, using the zebrafish as a model system, shed new light on the intricate relationship between TB and DM2, in particular on the role of leptin, SHP-1 and glucocorticoids.Leptin plays an important role during TB infection and has a huge impact on insulin sensitivity in zebrafish larvae. Similarly to what has been observed in the murine model, leptin deficiency in zebrafish increased the bacterial burden and mortality during the infection, leading to hyperglycemia and the development of insulin resistance. In addition, a novel SHP-1/SHP-2 inhibitor, NSC-87877, was shown to represent a promising anti-diabetic drug that can be used for further DM2 research, as it is able to rescue the phenotype of the leptin-deficient zebrafish and to restore glucose transport to the tissues. In contrast to metformin, NSC-87877 can act at very early developmental stages and inhibits the function of SHP-1 and factors that underlay impaired glucose metabolism, whereas metformin is mostly known to improve insulin sensitivity. Additionally, treatment with the glucocorticoid beclomethasone attenuates the metabolic changes associated with the infection, and transcriptional alterations induced by beclomethasone treatment suggest that genes involved in glucose metabolism, insulin and leptin signaling all play an important role in the modulation of the metabolism.Our data show that zebrafish larvae represent an interesting model system to investigate the complex pathology of TB, and the studies described in this thesis in which this model has been used have provided novel insights into the molecular mechanisms underlying wasting syndrome and the possibilities for adjunctive glucocorticoid therapy to alleviate this metabolic state. Show less
This thesis is focused on the innate immune defence mechanisms responsible for controlling mycobacterial growth after infection. To provide a detailed description of the host__s innate immune... Show moreThis thesis is focused on the innate immune defence mechanisms responsible for controlling mycobacterial growth after infection. To provide a detailed description of the host__s innate immune response to M. marinum infection, zebrafish gene expression levels were analysed by RNA sequencing at various time points during infection and correlated with imaging data of the process of pathogenesis. We demonstrate that the scavenger receptor Marco (macrophage receptor with collagenous structure) is a key player in the rapid phagocytosis of M. marinum and we use gene expression analysis in combination with gene knockdown studies to show that it is also essential in the establishment of an initial transient pro-inflammatory response to M. marinum infection. Once phagocytosed, M. marinum is capable of avoiding killing mechanisms of the host cell and can continue to grow within macrophages. This is the period when Membrane Attack Complex/Perforin proteins are involved in killing intracellular bacteria by their pore-forming activities. We reveal the regulatory mechanisms and function of two macrophage specific genes, mpeg1 and mpeg1.2 (macrophage expressed gene 1.2). The results from this thesis complement knowledge obtained from other model organisms by providing new insights into both counteracting and supporting mechanisms underlying the innate immune response. Show less
In a world where bacterial infections are becoming harder and harder to fight due to rising antibiotic resistance, disease models that allow high throughput screening are needed more than ever. An... Show moreIn a world where bacterial infections are becoming harder and harder to fight due to rising antibiotic resistance, disease models that allow high throughput screening are needed more than ever. An ideal model organism for high throughput screening is the zebrafish embryo. However, models for high throughput screening of infection are still wanted. In this thesis the fish pathogen Edwardsiella tarda was tested for use in high throughput studies of infectious disease in zebrafish. First the genome of Edwardsiella tarda was sequenced to determine the virulence factors of this bacterium. Next different types of exposure of zebrafish to Edwardsiella tarda were tested. This showed an absence of detectable infection after static immersion, but a reproducible infection on the level of single embryos after caudal vein injection. Finally, using the caudal vein injection method, the zebrafish knock-out mutant in the gene Myd88 was characterized. This is the first zebrafish knock-out mutant in a gene central in the innate immune system. Show less
In the last decade the study of the innate immune system has gained renewed scientific momentum as a result of the discovery of essential receptor families, such as the Toll-like receptor (TLR)... Show moreIn the last decade the study of the innate immune system has gained renewed scientific momentum as a result of the discovery of essential receptor families, such as the Toll-like receptor (TLR) family, that are required for pathogen recognition. These receptors detect specific molecular structures of microorganisms and in turn are able to trigger host immune responses. The work described in this thesis focuses on the use of the zebrafish embryo as a model to study the vertebrate immune system in order to gain new insights into the mechanisms of innate immune defence against bacterial infections and TLR signalling. Making use of a Salmonella infection model in combination with microarray technology and gene knock-down studies we were able to thoroughly characterize the embryonic host transcriptome response to a bacterial infection. Furthermore, we have demonstrated important functions for key signalling molecules in the innate immune response, including Tlr5, MyD88 and Traf6 and discovered new downstream targets of the TLR signalling pathway. The data presented here will enable in-depth functional follow-up studies that will provide new insights into the mechanisms of innate immune defence systems. This, in combination with future applications of zebrafish embryo infection models in high-throughput compound screens, holds much promise for the discovery of novel anti-microbial and anti-inflammatory drugs. Show less
