Project description:This SuperSeries is composed of the following subset Series: GSE9626: Comparison between saprotrophic and biotrophic-like mycelia of cacao WBD causal agent Moniliophthora perniciosa GSE9627: Comparison between saprotrophic and biotrophic-like mycelia of cacao WBD causal agent Moniliophthora perniciosa II Keywords: SuperSeries Refer to individual Series
Project description:Moniliophthora perniciosa is the causal agent of cacao Witche´s broom disease. This disease has been causing extensive damages to Brazilian cacao plantation, especially in Southern Bahia. Using glass slides microarrays, we analyzed the expression profile of 3872 whole genome shotgun reads from M. perniciosa genome, comparing two stages of development (Biotrophic-like mycelia and saprotrophic mycelia). Keywords: Moniliophthora perniciosa, Witches Broom Disease, Pathogenesis, Cacao Pools from RNA of axenic cultures were amplified by RNA technique and labeled with Cyanine-3 CTP and Cyanine-5 CTP. Comparison was performed between biotrophic and necrotrophic mycelia, both grown in glycerol with cacao meristem extracts, using saprotrophic mycelia grown in glycerol as a control.
Project description:Moniliophthora perniciosa is the causal agent of cacao Witche´s broom disease. This disease has been causing extensive damages to Brazilian cacao plantation, especially in Southern Bahia. Using glass slides microarrays, we analyzed the expression profile of 3872 whole genome shotgun reads from M. perniciosa genome, comparing two stages of development (Biotrophic-like mycelia and saprotrophic mycelia). Keywords: Moniliophthora perniciosa, Witches Broom Disease, Pathogenesis, Cacao Pools from RNA of axenic cultures were amplified by RNA technique and labeled with Cyanine-3 CTP and Cyanine-5 CTP. Comparison was performed between biotrophic and necrotrophic mycelia, both grown in glycerol with cacao meristem extracts, using saprotrophic mycelia grown in glycerol as a control.
Project description:Cellular differentiation is instructed by development regulators in coordination with chromatin remodeling complexes. Much information about their coordination comes from studies in the model ascomycetous yeasts. It is not clear, however, of the kind of information that can be extrapolated to species of other phyla in Kingdom Fungi. In the basidiomycete Cryptococcus neoformans, the transcription factor Znf2 controls yeast-to-hypha differentiation. Through a forward genetic screen, we identified the basidiomycete-specific factor Brf1 and discovered that it works together with Snf5 in the SWI/SNF chromatin remodeling complex in concert with existent Znf2 to execute cellular differentiation. We demonstrated that SWI/SNF assists Znf2 opening up the promoter regions of hyphal specific genes, including the ZNF2 gene itself. In addition, this complex supports Znf2 to fully associate with its target regions. Importantly, our findings revealed key differences in composition and biological function of the SWI/SNF complex in the two major phyla of Kingdom Fungi.
Project description:The response mechanisms, recognition and specificity of conifer trees during interaction with pathogenic, saprotrophic or symbiotic ectomycorrhizal fungus were investigated. The roots of Pinus sylvestris were challenged for fifteen days with either Heterobasidion annosum (a pathogenic root rot fungus which attacks Norway spruce, Scots pine and broad leaf trees); Laccaria bicolor (an obligate ectomycorrhizal symbiont); or Trichoderma aureoviride (an obligate saprotroph). The gene expression data from cDNA micro-arrays consisting of 2176 Pinus taeda genes were analysed using 2-interconnected mixed linear model statistical approach. The result of the pairwise comparisons of the different treatments against un-inoculated control led to identification of genes specifically differentially expressed in the pathogenic, saprotrophic and symbiotic interactions. The results were compared with similar data obtained for two other interaction stages: 1 and 5 days post inoculation. The result of this comprehensive expression profiling will hopefully shed more light on the mechanistic basis for recognition and response of conifer trees to pathogenic and non-pathogenic fungi. Keywords: stress response
