Molecular mechanisms of virulence of fungal wheat pathogens
- Praz, Coraline - Otros postdoctorales de programas oficiales
- Suárez Fernández, Marta - Postdoctoral Fellow
Fungal pathogens, such as Zymoseptoria tritici, the causal agent of Septoria tritici blotch in wheat, have an intimate interaction with their hosts. Not only do they have to acquire nutrients from them, but they also have to protect themselves against the host immune system. The molecular mechanisms by which plant pathogenic fungi infect their hosts have been studied for years. However, the molecular components that determine specificity between the plant and the host still remain enigmatic. In our group, we are interested in analyzing the molecular mechanisms by which Z. tritici infects host plants. Specifically, we are interested in analyzing how this fungal pathogen is able to cope with the host immune system and how it eventually kills the cells. The aim of my research is to gain knowledge into the molecular basis of infection of Z. tritici.
1. Z. tritici pathogenicity
Z. tritici is a highly specialized pathogen that only infects wheat and no other plants. In this project, we aim to understand the molecular mechanisms by which Z. tritici infects wheat and adapt to its host. One of our main goals is to identify the key molecular components involved in the interaction between both microorganisms by using population genetics approaches. We recently identified a new avirulence factor which is specifically recognized by certain wheat cultivars hindering the infection progression. The gene is highly polymorphic and specifically expressed during host colonization. To understand the molecular basis of recognition and the molecular targets of effectors, we functionally characterize candidate genes and perform biochemical analyses.
Figure 1: leaves of the wheat cultivar Runal spray‐infected with Zymoseptoria tritici strains 3D1 and 3D7 and harvested at different days post‐inoculation (dpi). (b) Fully necrotised leaves with pycnidia of cv Runal infected by 3D1 and 3D7 at 21 dpi.
2. Chromatin remodeling and expression of effector genes
Tight gene expression regulation of virulence factors is required for successful colonization of the host. Although it is frequently assumed that chromatin remodeling is required for induction of expression of effectors, we still do not understand the molecular components involved in this process. We recently demonstrated that host-triggered chromatin remodeling is involved in cell-specific expression profiles of effector genes. In this project, we aim to elucidate how stress related genes are activated during infection and what is the contribution of chromatin remodeling in gene expression regulation.
Figure 2: The effector gene AvrStb6 is silenced under axenic conditions and on hyphae growing on the leaf surface, but de-repressed during apoplast colonization. Fluorescence of mCherry and mTurquoise2 of Z. tritici strain 3D7 during infection of wheat leaves. His1-mCherry fusion protein is under the control of the AvrStb6 promoter and mTurquoise2 under the control of the constitutive α-tubulin promoter.
3. Dialogue between strains in genetically diverse infections
Natural infections are often caused by mixtures of genetically different pathogen strains (mixed-infections). Most research projects aim to understand the interactions of individual hosts with single pathogen strains. In mixed infections, pathogens not only have to overcome the host resistance response, they also have to compete with other pathogenic strains to achieve successful infection. Mixed infections have strong consequences for the progress of the infection, for the evolution of virulence and for the epidemiology. Until now, the molecular components involved in interactions between co-infecting strains remain to be elucidated, but effectors have been proposed to be involved. The aim of this research project is to gain understanding of the molecular components involved in the interaction between fungal strains and the impact of the host on the outcome of mixed infections.
Figure 3: Co-infecting hyphae of different strains co-exist in wheat. Confocal microscopy analysis of cultivar Drifter infected with one strain of Z. tritici expressing cytosolic eGFP and the other strain expressing cytosolic mCherry.
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