Project description:We used mRNA sequencing to study the effects of foliar piperonylic acid treatment on the transcriptome of rice plants (cv. Nipponbare) and infection by M. graminicola to gain insights in the molecular basis of piperonylic acid-induced disease resistance against this nematode

Project description:Transcriptome analysis of piperonylic acid-treated, Meloidogyne graminicola-inoculated rice roots

Project description:Transcriptome analysis of piperonylic acid-treated, Meloidogyne graminicola-inoculated rice roots [6 and 24h after treatment]

Project description:We used mRNA sequencing to study the effects of foliar treatment with piperonylic acid, acibenzolar-S-methyl or beta-aminobutyric acid on the root transcriptome of rice plants (cv. Kitaake) in order to find conserved systemic responses to distinct resistance-inducing stimuli

Project description:Meloidogyne graminicola overview

Project description:Meloidogyne graminicola Genome sequencing

Project description:We used mRNA sequencing to study the effects of piperonylic acid treatment on the transcriptome of tomato plants (cv. Moneymaker) to gain insights in the molecular basis of piperonylic acid-induced disease resistance

Project description:Meloidogyne graminicola Raw sequence reads

Project description:Meloidogyne graminicola Transcriptome or Gene expression

Project description:Contrary to the relative wealth of information regarding pathogen defense responses in aboveground plant parts, little is known about the mechanistic basis and regulation of plant immunity in root tissues. Aiming to further our fundamental understanding of root immune responses, we have investigated the interaction between rice and one of its major root pathogens, the oomycete Pythium graminicola. The specificic objectives of this study were twofold: i) to disentangle the molecular and genetic basis of the rice-Pythium interaction by comparing the transcriptome of rice roots at different times after inoculation with a highly virulent Pythium strains, and ii) to offer fundamental insights into the genetic architecture and regulation of rice disease resistance pathways operative in root tissue and to identify the molecular players controlling the possible nodes of convergence between these resistance conduits Comparison between P. graminicola- and mock-infected rice roots. Two treatments (infected and non-infected) x three timepoints (1, 2 and 4 days post inoculation) x three biological replicates