Project description:pine forest succession

Project description:Bursaphelenchus xylophilus is known as the causative agent of pine wilt disease with complex life cycles. In this research, newly published Bursaphelenchus xylophilus genome data were employed to annotate its miRNAs based on deep sequencing technologies. Four small RNA libraries derived from different infection stages of pine wilt disease were constructed and sequenced. Consequently, we obtained hundreds of evolutionarily conserved miRNAs as well as novel miRNA candidates. The analysis of miRNA expression patterns showed that most miRNAs were expressed at extraordinarily high levels during the middle stage of pine wilt disease. Subsequent stem-loop RT-PCR experiments were carried out to validate our results. Functional analysis proved that expression levels of miR-73 and miR-239 were mutually exclusive with their target GH45 cellulase genes., genes known to be responsible for the degradation of the pine cell walls. In addition, another set of atypical miRNAs, termed mirtrons, were identified from B. xylophilus introns. This discovery has expanded the current knowledgebase of such splicing-derived miRNAs into B. xylophilus. Thus, our research has provided detailed characterization of B. xylophilus miRNAs expression patterns during the pathological process of pine wilt disease. The findings will contribute to more in-depth understanding of this devastating plant disease.

Project description:Changes in bacterial communities and functions associated with litter degradation during forest succession caused by forest disease.

Project description:Changes in bacterial communities and functions associated with litter degradation during forest succession caused by forest disease

Project description:Bursaphelenchus xylophilus is known as the causative agent of pine wilt disease with complex life cycles. In this research, newly published Bursaphelenchus xylophilus genome data were employed to annotate its miRNAs based on deep sequencing technologies. Four small RNA libraries derived from different infection stages of pine wilt disease were constructed and sequenced. Consequently, we obtained hundreds of evolutionarily conserved miRNAs as well as novel miRNA candidates. The analysis of miRNA expression patterns showed that most miRNAs were expressed at extraordinarily high levels during the middle stage of pine wilt disease. Subsequent stem-loop RT-PCR experiments were carried out to validate our results. Functional analysis proved that expression levels of miR-73 and miR-239 were mutually exclusive with their target GH45 cellulase genes., genes known to be responsible for the degradation of the pine cell walls. In addition, another set of atypical miRNAs, termed mirtrons, were identified from B. xylophilus introns. This discovery has expanded the current knowledgebase of such splicing-derived miRNAs into B. xylophilus. Thus, our research has provided detailed characterization of B. xylophilus miRNAs expression patterns during the pathological process of pine wilt disease. The findings will contribute to more in-depth understanding of this devastating plant disease. For the purposes of this study, we classified the pathogenic process associated with PWD into three stages in order to best characterize the expression patterns of microRNAs during the development of this devastating disease. The following describes the first stage (F): about seven days after pine trees are infected with PWNs, the tips of the pine needles begin to turn brown. Next, the middle stage (M) ensues approximately seven days later, when half of the needles on pine trees turn brown. The last stage (L) occurs another 10 days later and pine needles are complete browning. PWNs cultured on Botrytis cinerea grown on PDA medium served as the control stage (C).

Project description:The pinewood nematode (PWN), Bursaphelenchus xylophilu (Bx) s, one of the most serious forest pests, worldwide, is considered the causal agent of the pine wilt disease (PWD). The main host species belong to the genus Pinus and a variation in the susceptibility of several pine species to PWN infection is well-known. Additionally, it is also recognized that there is variation in the virulence among different B. xylophilus isolates. In the present study, we applied a quantitative mass spectrometry-based proteomics approach to perform a deep characterization of proteomic changes across two B. xylophilus isolates from different hosts and geographical origins and with different virulence. A total of 1456 proteins were quantified and compared between the two isolates secretomes and a total of 2741 proteins were quantified and compared between the nematode proteomes in two different conditions, pine tree extract and fungus stimuli.

Project description:Bursaphelenchus xylophilus (pinewood nematode, PWN) is a causal agent of pine wilt disease and results in economic and environmental losses in pine forests. The establishment of systemic acquired resistance (SAR) provides positive capacities to control PWN. We selected two SAR elicitors, acibenzolar-S-methyl (ASM) and methyl salicylic acid (MeSA), which effectively inhibited disease symptoms on PWN-infected pine trees. To understand dynamic interactions between pine host and PWN under SAR state, we characterized in vivo transcriptomes of pine trees infected by B. xylophilus according to the ASM and MeSA treatment. After distilled water treatment, pine trees infected by B. xylophilus was used as a negative control.

Project description:Bursaphelenchus xylophilus (pinewood nematode, PWN) is the causal agent of pine wilt disease, causing economic and environmental losses in pine forests. The establishment of systemic acquired resistance (SAR) offers positive prospects for PWN control. We chose Bacillus subtilis JCK-1398, which effectively mitigated disease symptoms in PWN-infected pine trees. To elucidate the molecular responses involved in increased SAR according to B. subtilis JCK-1398 treatment, we characterized the in vivo transcriptomes of pine trees infected by PWN with B. subtilis JCK-1398 treatment. Additionally, pine trees infected by PWN after Tween20 treatment were used as a negative control.

Project description:DNA methylation is a pivotal process that regulates gene expression and facilitates rapid adaptation to challenging environments. The pine wood nematode (PWN; Bursaphelenchus xylophilus), the causative agent of pine wilt disease, survives and spreads at low temperatures through third-stage dispersal larvae, making it a major pathogen for pine wood in Asia. To comprehend the impact of DNA methylation on the formation and environmental adaptation of third-stage dispersal larvae, we conducted whole-genome bisulfite sequencing and transcriptional sequencing on both the third-stage dispersal larvae and three other stages propagative larvae of PWN.

Project description:DNA methylation is a pivotal process that regulates gene expression and facilitates rapid adaptation to challenging environments. The pine wood nematode (PWN; Bursaphelenchus xylophilus), the causative agent of pine wilt disease, survives and spreads at low temperatures through third-stage dispersal larvae, making it a major pathogen for pine wood in Asia. To comprehend the impact of DNA methylation on the formation and environmental adaptation of third-stage dispersal larvae, we conducted whole-genome bisulfite sequencing and transcriptional sequencing on both the third-stage dispersal larvae and three other stages propagative larvae of PWN.