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Viral infections induce a significant impact on various functional categories of biological processes in the host. The understanding of this complex modification of the infected host immune system requires a global and detailed overview on the infection process. Therefore it is essential to apply a powerful approach which identifies the involved components conferring the capacity to recognize and respond to specific pathogens, which in general are defeated in so-called compatible virus-plant infections. Comparative and integrated systems biology of plant-virus interaction progression may open a novel framework for a systemic picture on the modulation of plant immunity during different infections and understanding pathogenesis mechanisms. In this thesis these approaches were applied to study plant-virus infections during two main viral pathogens of cassava: Cassava brown streak virus and African cassava mosaic virus.
Here, the infection process was reconstructed by a combination of omics data-based analyses and metabolic network modelling, to understand the major metabolic pathways and elements underlying viral infection responses in different time series, as well as the flux activity distribution to gain more insights into the metabolic flow and mechanism of regulation; this resulted in simultaneous investigations on a broad spectrum of changes in several levels including the gene expression, primary metabolites, and enzymatic flux associated with the characteristic disease development process induced in Nicotiana benthamiana plants due to infection with CBSV or ACMV.
Firstly, the transcriptome dynamics of the infected plant was analysed by using mRNA-sequencing, in order to investigate the differential expression profile according the symptom developmental stage. The spreading pattern and different levels of biological functions of these genes were analysed associated with the infection stage and virus entity. A next step was the Real-Time expression modification of selected key pathway genes followed by their linear regression model. Subsequently, the functional loss of regulatory genes which trigger R-mediated resistance was observed. Substantial differences were observed between infected mutants/transgenic lines and wild-types and characterized in detail. In addition, we detected a massive localized accumulation of ROS and quantified the scavenging genes expression in the infected wild-type plants relative to mock infected controls.
Moreover, we found coordinated regulated metabolites in response to viral infection measured by using LC-MS/MS and HPLC-UV-MS. This includes the profile of the phytohormones, carbohydrates, amino acids, and phenolics at different time points of infection with the RNA and DNA viruses. This was influenced by differentially regulated enzymatic activities along the salicylate, jasmonate, and chorismate biosynthesis, glycolysis, tricarboxylic acid cycle, and pentose phosphate pathways, as well as photosynthesis, photorespiration, transporting, amino acid and fatty acid biosynthesis. We calculated the flux redistribution considering a gradient of modulation for enzymes along different infection stages, ranging from pre-symptoms towards infection stability.
Collectively, our reverse-engineering study consisting of the generation of experimental data and modelling supports the general insight with comparative and integrated systems biology into a model plant-virus interaction system. We refine the cross talk between transcriptome modification, metabolites modulation and enzymatic flux redistribution during compatible infection progression. The results highlight the global alteration in a susceptible host, correlation between symptoms severity and the alteration level. In addition we identify the detailed corresponding general and specific responses to RNA and DNA viruses at different stages of infection. To sum up, all the findings in this study strengthen the necessity of considering the timing of treatment, which greatly affects plant defence against viral infection, and might result in more efficient or combined targeting of a wider range of plant pathogens.
Visualization of type I immunity using bicistronic IFN-gamma reporter mice in vitro and in vivo
(2006)
IFN-γ is the signature cytokine of Th1 and CD8+ effector cells generated in type I immune responses against pathogens, such as Influenza virus, Sendai virus and the intracellular protozoan parasite Toxoplasma gondii. Understanding the regulation of IFN-γ is critical for the manipulation of immune responses, prevention of immunopathology and for vaccine design. In the present thesis, IFN-γ expression by CD4+ and CD8+ T cells was characterized in detail and the requirement of IFN-γ receptor mediated functions for IFN-γ expression was assessed. Bicistronic IFN-γ-eYFP reporter mice, which allow direct identification and isolation of live IFN-γ expressing cells, were used to visualize IFN-γ expression in vitro and in vivo after infection with the afore mentioned pathogens. Expression of the IFN-γ-eYFP reporter by CD4+ and CD8+ T cells was broadly heterogeneous in vitro and in vivo after infection. Increased expression of the reporter correlated positively with the abundance of IFN-γ transcripts and IFN-γ protein production upon stimulation. eYFP reporter brightness reflected the potential for IFN-γ production, but actual secretion was largely dependent on antigenic stimulation. Increased expression of the reporter also correlated with enhanced secretion of additional proinflammatory cytokines and chemokines and cell surface expression of markers that indicate recent activation. Highly eYFP fluorescent cells were generally more differentiated and their anatomical distribution was restricted to certain tissues. The anatomical restriction depended on the pathogen. IFN-γ expressing CD4+ and CD8+ T cells were generated in IFN-γ receptor deficient reporter mice after infection with Sendai virus or Toxoplasma gondii. However, in the absence of IFN-γ receptor mediated functions, the frequency and brightness of the eYFP reporter expression was altered. Dual BM chimeric mice, reconstituted with wild-type and IFN-γ receptor deficient reporter BM, revealed a T cell-intrinsic requirement for the IFN-γ receptor for optimal IFN-γ expression. Reporter fluorescence intensities were regulated independently of IFN-γ receptor mediated functions. Finally, we propose a model for IFN-γ expression by CD4+ and CD8+ T cells. 2. SUMMARY 10 In summary, the expression of IFN-γ is differentially regulated in CD4+ and CD8+ T cells and after viral or protozoan infections. Additionally, the role of IFN-γ receptor mediated functions for the expression of IFN-γ was determined.