Project description:Marssonina coronariae Genome sequencing and assembly

Project description:Marssonina coronariae Genome sequencing and assembly

Project description:Marssonina coronariae strain:NL1 Genome sequencing and assembly

Project description:Marssonina coronariae strain:LL1 Genome sequencing and assembly

Project description:Marssonina coronariae strain:GW01-2013 Genome sequencing

Project description:Gene expression profiles of Populus deltoides induced by fungal pathogenic Marssonina brunneain iduring time-course infection. We used Affymetrix poplar genome genechip microarrays to analyze the full transcript expression underlying time-course infection and identified significantly differently expressed genes during the infection process.

Project description:Gene expression profiles of Populus deltoides induced by fungal pathogenic Marssonina brunneain iduring time-course infection. We used Affymetrix poplar genome genechip microarrays to analyze the full transcript expression underlying time-course infection and identified significantly differently expressed genes during the infection process. 2-year-old seedlings of P. deltoides grown were innoculated with the suspension of the pathogenic spores throught leaves spraying. Collecting the samples at interval time of 2 days and one week. Affymetrix poplar genechip was hired to investigate the full transcripts changed of the poplar response to the pathogen attack during the time.

Project description:Marssonina coronaria Ellis & Davis is a filamentous fungus in the class Leotiomycetes that causes apple blotch, an economically important disease of apples worldwide. Here, we sequenced the whole genome of M. coronaria strain NL1. The genome contained 50.3 Mb with 589 scaffolds and 9,622 protein-coding genes. A phylogenetic analysis using multiple loci and a whole-genome alignment revealed that M. coronaria is closely related to Marssonina rosae and Marssonina brunnea. A comparison of the three genomes revealed 90 species-specific carbohydrate-active enzymes, 19 of which showed atypical distributions, and 12 species-specific secondary metabolite biosynthetic gene clusters, two of which have the potential to synthesize products analogous to PR toxin and swainsonine, respectively. We identified 796 genes encoding for small secreted proteins in Marssonina spp., many encoding for unknown hypothetical proteins. In addition, we revealed the genetic architecture of the MAT1-1 and MAT1-2 mating-type loci of M. coronaria, as well as 16 tested isolates carrying either MAT1-1 idiomorph (3) or MAT1-2 idiomorph (13). Our results showed a series of species-specific carbohydrate-active enzyme, secondary metabolite biosynthetic gene clusters and small-secreted proteins that may be involved in the adaptation of Marssonina spp. to their distinct hosts. We also confirmed that M. coronaria possesses a heterothallic mating system and has outcrossing potential in nature.

Project description:Marssonina coronaria associated with apple blotch disease causes severe premature defoliation, and is widely distributed in Korea. Thirteen isolates were collected from orchards located in Gyeongbuk Province from 2005~2007. All isolates displayed over 99.6% and 99.2% sequence similarity to each other in internal transcribed spacer regions and partial sequences of 28S rDNA, respectively. The isolates were phylogenetically closely related to Chinese isolates. Selected isolates did not differ in their pathogenicity. The optimum conditions for fungal growth were 20? and pH 6 on peptone potato dextrose agar (PPDA). Peptone and mannose were the best nitrogen and carbon source, respectively. Fungal growth was better on PPDA than on common potato dextrose agar. This study provides valuable information for integrated disease management program and facilitates the routine culturing of M. coronaria.

Project description:BACKGROUND: The fungus Marssonina brunnea is a causal pathogen of Marssonina leaf spot that devastates poplar plantations by defoliating susceptible trees before normal fall leaf drop. RESULTS: We sequence the genome of M. brunnea with a size of 52 Mb assembled into 89 scaffolds, representing the first sequenced Dermateaceae genome. By inoculating this fungus onto a poplar hybrid clone, we investigate how M. brunnea interacts and co-evolves with its host to colonize poplar leaves. While a handful of virulence genes in M. brunnea, mostly from the LysM family, are detected to up-regulate during infection, the poplar down-regulates its resistance genes, such as nucleotide binding site domains and leucine rich repeats, in response to infection. From 10,027 predicted proteins of M. brunnea in a comparison with those from poplar, we identify four poplar transferases that stimulate the host to resist M. brunnea. These transferas-encoding genes may have driven the co-evolution of M. brunnea and Populus during the process of infection and anti-infection. CONCLUSIONS: Our results from the draft sequence of the M. brunnea genome provide evidence for genome-genome interactions that play an important role in poplar-pathogen co-evolution. This knowledge could help to design effective strategies for controlling Marssonina leaf spot in poplar.