Project description:Fritillaria thunbergii overview

Project description:Fritillaria thunbergii Miq. Transcriptome sequencing

Project description:Fritillaria thunbergii Raw sequence reads

Project description:RNA sequencing of Fritillaria thunbergii

Project description:Fritillaria thunbergii Genome sequencing and assembly

Project description:Fritillaria thunbergii Transcriptome or Gene expression

Project description:Transcriptome of towards Fritillaria thunbergii Bulbus

Project description:This study compared the different gene expression of Bursaphelenchus xylophilus in two growth conditions (growing on Botrytis cinerea and inoculating Pinus thunbergii). The goal was to analyze the specifically-expressed genes of the pine wood nematode involved in the early interaction between B. xylophilus and P. thunbergii and screen the pathogenesis related genes of B. xylophilus.

Project description:This study compared the different gene expression of Bursaphelenchus xylophilus in two growth conditions (growing on Botrytis cinerea and inoculating Pinus thunbergii). The goal was to analyze the specifically-expressed genes of the pine wood nematode involved in the early interaction between B. xylophilus and P. thunbergii and screen the pathogenesis related genes of B. xylophilus. Two-condition experiment, Growing on Botrytis cinerea vs. Inoculating Pinus thunbergii . Biological replicates: 3 replicates.

Project description:<p>Dried bulbs of Fritillaria thunbergii Miq. (Liliaceae family) are medicinal materials used to clear heat and resolve phlegm. However, premature plant etiolation during cultivation reduces yield and hampers the industrial development of these plants. This study compared agronomic traits, soil properties, enzyme activities, microbial communities, and metabolomic profiles between healthy and etiolated plants, in order to explore rhizosphere microecological changes. The results showed that etiolated plant biomass decreased by 57.58%. Although peimine and peiminine levels increased by 26.09% and 18.31%, respectively, total alkaloid accumulation decreased by 37.13%. In the rhizosphere soil of etiolated plants, total nitrogen and organic matter decreased, whereas invertase and urease activities increased. The rhizosphere of etiolated plants showed enrichment in microbial genera such as Clitopilus, which enhanced tryptophan and diterpenoid metabolism in the rhizosphere and plant tissues, increasing bioactive component content. Conversely, the decreased abundance of genera, including Bacillus, impaired isoflavone and tyrosine metabolism, reducing plant resistance. This study revealed correlations among rhizosphere microecology, plant etiolation, and variations in bioactive components, providing insights into improving the yield and quality of F thunbergii through rhizostheric regulation.</p>