Project description:The hemibiotrophic fungus Magnaporthe oryzae produces specialized biotrophic invasive hyphae (IH) that alter membrane structure and defense responses in invaded rice cells. IH successively invade live neighbor cells, apparently through plasmodesmata. Understanding fungal and rice genes that contribute to biotrophic invasion has been a challenge because so few plant cells have encountered IH at the earliest infection stages. Using a rice sheath inoculation method, we successfully enriched for infected tissue RNA that contained ~20% fungal RNA at a point when most IH were still growing in first-invaded rice cells. The RNAs were analyzed using the whole-genome M. oryzae oligoarray and a rice oligoarray. Rice genes that were induced >50-fold during infection were enriched for genes involved in transferring information from sensors to cellular responses. Fungal genes that were induced >50-fold in IH included the PWL2 avirulence gene and genes encoding hypothetical secreted proteins. The IH-specific secreted proteins are candidate effectors, proteins that the fungus secretes into live host cells to control cellular processes. Gene knock-out analyses of three putative effector genes failed to show major effects on pathogenicity. Details of the blast interaction transcriptome will provide insights on the mechanisms of biotrophic plant disease. Keywords: Disease state analysis Our goal was to compare expression in biotrophic IH to expression in mycelium grown in nutrient medium, and to compare expression in infected rice sheath to expression in mock inoculated rice. Using version 2 of the fungal whole genome microarray (Agilent Technologies), we analyzed samples from three biological replicates of rice leaf sheath at 36 hours after inoculation with the rice blast fungus M. oryzae. The same samples were used with the Agilent rice microarray (see series GSE8518). To estimate the ratio of fungal to rice RNAs in the infected sheaths, we compared RT-PCR amplification of fungal genes in infected tissue to amplification in standards produced by mixing known ratios of pure mycelial RNA with mock-inoculated rice RNA. Using this assay, fungal RNA content in infected tissues were approximately 20% of the total RNAs. We prepared control mixtures by pooling 20% mycelial RNA and 80% RNA from mock-inoculated rice sheath. Complementary RNAs from infected tissues were labeled with Cy3 or Cy5 and hybridized together with the control mixture RNA labeled with the other dye. Three independent biological replications were performed, with separate hybridizations for 2 technical replications and corresponding dye swap experiments. Data were analyzed by Rosetta Resolver® and showed a correlation of over 80% between biological replications.

Project description:This SuperSeries is composed of the following subset Series: GSE8517: Magnaporthe oryzae gene expression during biotrophic invasion of rice using version 2 of the Agilent Magnaporthe grisea Array (G4137B). GSE8518: Rice gene expression during biotrophic invasion by the rice blast fungus Magnaporthe oryzae using the Agilent Rice Array (G4138A). Keywords: SuperSeries Refer to individual Series

Project description:The hemibiotrophic fungus Magnaporthe oryzae produces specialized biotrophic invasive hyphae (IH) that alter membrane structure and defense responses in invaded rice cells. IH successively invade live neighbor cells, apparently through plasmodesmata. Understanding fungal and rice genes that contribute to biotrophic invasion has been a challenge because so few plant cells have encountered IH at the earliest infection stages. Using a rice sheath inoculation method, we successfully enriched for infected tissue RNA that contained ~20% fungal RNA at a point when most IH were still growing in first-invaded rice cells. The RNAs were analyzed using the whole-genome M. oryzae oligoarray and a rice oligoarray. Rice genes that were induced >50-fold during infection were enriched for genes involved in transferring information from sensors to cellular responses. Fungal genes that were induced >50-fold in IH included the PWL2 avirulence gene and genes encoding hypothetical secreted proteins. The IH-specific secreted proteins are candidate effectors, proteins that the fungus secretes into live host cells to control cellular processes. Gene knock-out analyses of three putative effector genes failed to show major effects on pathogenicity. Details of the blast interaction transcriptome will provide insights on the mechanisms of biotrophic plant disease. Keywords: Disease state analysis

Project description:The hemibiotrophic fungus Magnaporthe oryzae produces specialized biotrophic invasive hyphae (IH) that alter membrane structure and defense responses in invaded rice cells. IH successively invade live neighbor cells, apparently through plasmodesmata. Understanding fungal and rice genes that contribute to biotrophic invasion has been a challenge because so few plant cells have encountered IH at the earliest infection stages. Using a rice sheath inoculation method, we successfully enriched for infected tissue RNA that contained ~20% fungal RNA at a point when most IH were still growing in first-invaded rice cells. The RNAs were analyzed using the whole-genome M. oryzae oligoarray and a rice oligoarray. Rice genes that were induced >50-fold during infection were enriched for genes involved in transferring information from sensors to cellular responses. Fungal genes that were induced >50-fold in IH included the PWL2 avirulence gene and genes encoding hypothetical secreted proteins. The IH-specific secreted proteins are candidate effectors, proteins that the fungus secretes into live host cells to control cellular processes. Gene knock-out analyses of three putative effector genes failed to show major effects on pathogenicity. Details of the blast interaction transcriptome will provide insights on the mechanisms of biotrophic plant disease. Keywords: Disease state analysis

Project description:The devastating blast fungus Magnaporthe oryzae elaborates invasive hyphae (IH) in living rice cells during early infection, separated from host cytoplasm by plant-derived interfacial membranes, but the metabolic strategies underpinning this fundamental intracellular biotrophic growth phase are poorly understood. Eukaryotic cell growth depends on activated target-of-rapamycin (TOR) kinase signaling, which inhibits autophagy. Here, using live-cell imaging coupled with multiomic approaches, we show how the M. oryzae serine/threonine protein kinase Rim15 coordinates cycles of autophagy and glutaminolysis in IH – the latter through phosphorylation of NAD-dependent glutamate dehydrogenase – to reactivate TOR and promote biotrophic growth. Deleting RIM15 attenuated IH growth and triggered plant immunity; these defects were fully remediated by exogenous α-ketoglutarate treatment, but glucose treatment only suppressed host defenses. Our results together suggest that Rim15-dependent cycles of autophagic flux liberate α-ketoglutarate – via glutaminolysis – to reactivate TOR signaling and fuel biotrophic growth while conserving glucose for antioxidation-mediated host innate immunity suppression.

Project description:Magnaporthe oryzae causes rice blast, the most devastating foliar fungal disease of cultivated rice. During disease development the fungus simultaneously maintains both biotrophic and necrotrophic growth corresponding to a hemi-biotrophic life style. The ability of M. oryzae to also colonize roots and subsequently develop blast symptoms on aerial tissue has been recognized. The fungal root infection strategy and the respective host responses are currently unknown. Global temporal expression analysis suggested a purely biotrophic infection process reflected by the rapid induction of defense response-associated genes at the early stage of root invasion and subsequent repression coinciding with the onset of intracellular fungal growth. The same group of down-regulated defense genes was increasingly induced upon leaf infection by M. oryzae where symptom development occurs shortly post tissue penetration. Our molecular analysis therefore demonstrates the existence of fundamentally different tissue-specific fungal infection strategies and provides the basis for enhancing our understanding of the pathogen life style. Experiment Overall Design: We investigated global transcriptome response overtime of Mock- and M. oryzae inoculated rice root tissue in vitro. Two independant replicates were perfomed for each treatments and samples were collected at 2, 4 and 6 days post-inoculation.

Project description:Magnaporthe oryzae causes rice blast, the most devastating foliar fungal disease of cultivated rice. During disease development the fungus simultaneously maintains both biotrophic and necrotrophic growth corresponding to a hemi-biotrophic life style. The ability of M. oryzae to also colonize roots and subsequently develop blast symptoms on aerial tissue has been recognized. The fungal root infection strategy and the respective host responses are currently unknown. Global temporal expression analysis suggested a purely biotrophic infection process reflected by the rapid induction of defense response-associated genes at the early stage of root invasion and subsequent repression coinciding with the onset of intracellular fungal growth. The same group of down-regulated defense genes was increasingly induced upon leaf infection by M. oryzae where symptom development occurs shortly post tissue penetration. Our molecular analysis therefore demonstrates the existence of fundamentally different tissue-specific fungal infection strategies and provides the basis for enhancing our understanding of the pathogen life style.

Project description:We created a mutant in the MAP kinase-encoding Pmk1 gene of the rice blast fungus Magnaporthe oryzae (pmk1AS) that renders the gene sensitive to inhibition by 1NA-PP1. Fungal gene expression was compared during infection of rice sheath by the M. oryzae pmk1AS mutant in the presence and absence of 1NA-PP1.

Project description:Many of the world’s most devastating crop diseases are caused by fungal pathogens which elaborate specialized infection structures to invade plant tissue. Here we present a quantitative mass spectrometry-based phosphoproteomic analysis of infection-related development by the rice blast fungus Magnaporthe oryzae, which threatens global food security. We mapped 8,005 phosphosites on 2,062 fungal proteins, revealing major re-wiring of phosphorylation-based signaling cascades during fungal infection. Comparingme phosphosite conservation across 41 fungal species reveals phosphorylation signatures specifically associated with biotrophic and hemibiotrophic fungal infection. We then used parallel reaction monitoring to identify phosphoproteins directly regulated by the Pmk1 MAP kinase that controls plant infection by M. oryzae. We define 33 substrates of Pmk1 and show that Pmk1-dependent phosphorylation of a newly identified regulator, Vts1, is required for rice blast disease. Defining the phosphorylation landscape of infection therefore identifies potential therapeutic interventions for control of plant diseases.

Project description:Many of the world’s most devastating crop diseases are caused by fungal pathogens which elaborate specialized infection structures to invade plant tissue. Here we present a quantitative mass spectrometry-based phosphoproteomic analysis of infection-related development by the rice blast fungus Magnaporthe oryzae, which threatens global food security. We mapped 8,005 phosphosites on 2,062 fungal proteins, revealing major re-wiring of phosphorylation-based signaling cascades during fungal infection. Comparingme phosphosite conservation across 41 fungal species reveals phosphorylation signatures specifically associated with biotrophic and hemibiotrophic fungal infection. We then used parallel reaction monitoring to identify phosphoproteins directly regulated by the Pmk1 MAP kinase that controls plant infection by M. oryzae. We define 33 substrates of Pmk1 and show that Pmk1-dependent phosphorylation of a newly identified regulator, Vts1, is required for rice blast disease. Defining the phosphorylation landscape of infection therefore identifies potential therapeutic interventions for control of plant diseases.