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Start Over Author "Wen, Xiaojian" Topic pinewood nematode
6 results on '"Wen, Xiaojian"'

3. Transcriptomic response of Pinus massoniana to infection stress from the pine wood nematode Bursaphelenchus xylophilus.

Author

An, Yibo, Li, Yongxia, Ma, Ling, Li, Dongzhen, Zhang, Wei, Feng, Yuqian, Liu, Zhenkai, Wang, Xuan, Wen, Xiaojian, and Zhang, Xingyao

Subjects
PINEWOOD nematode, CONIFER wilt, PINE, GENE regulatory networks, GENETIC transcription regulation, TRANSCRIPTOMES, CELLULAR signal transduction
Abstract

The pinewood nematode (PWN) Bursaphelenchus xylophilus is a forestry quarantine pest and causes an extremely dangerous forest disease that is spreading worldwide. Due to the complex pathogenic factors of pine wood nematode disease, the pathogenesis is still unknown. B. xylophilus ultimately invades a host and causes death. However, little is known about the defence-regulating process of host pine after infection by B. xylophilus at the molecular level. Therefore, we wanted to understand how Pinus massoniana regulates its response to invasion by B. xylophilus. P. massoniana were artificially inoculated with B. xylophilus solution, while those without B. xylophilus solution were used as controls. P. massoniana inoculated with B. xylophilus solution for 0 h, 6 h, 24 h, and 120 h was subjected to high-throughput sequencing to obtain transcriptome data. At various time points (0 h, 6 h, 24 h, 120 h), gene transcription was measured in P. massoniana inoculated with PWN. At different time points, P. massoniana gene transcription differed significantly, with a response to early invasion by PWN. According to Gene Ontology (GO) classification and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis, P. massoniana response to PWN invasion involves a wide range of genes, including plant hormone signal transformation, flavonoid biosynthesis, amino sugar and nucleoside sugar metabolism, and MAPK signalling pathways. Among them, inoculation for 120 hours had the greatest impact on differential genes. Subsequently, weighted gene coexpression network analysis (WGCNA) was used to analyse transcriptional regulation of P. massoniana after PWN infection. The results showed that the core gene module of P. massoniana responding to PWN was "MEmagenta", enriched in oxidative phosphorylation, amino sugar and nucleotide sugar metabolism, and the MAPK signalling pathway. MYB family transcription factors with the highest number of changes between infected and healthy pine trees accounted for 20.4% of the total differentially expressed transcription factors. To conclude, this study contributes to our understanding of the molecular mechanism of initial PWN infection of P. massoniana. Moreover, it provides some important background information on PWN pathogenic mechanisms. [ABSTRACT FROM AUTHOR]

Published
2023
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4. The Changes of Microbial Communities and Key Metabolites after Early Bursaphelenchus xylophilus Invasion of Pinus massoniana.

Author

An, Yibo, Li, Yongxia, Ma, Ling, Li, Dongzhen, Zhang, Wei, Feng, Yuqian, Liu, Zhenkai, Wang, Xuan, Wen, Xiaojian, and Zhang, Xingyao

Subjects
PINEWOOD nematode, MICROBIAL communities, PINE, BACTERIAL communities, FUNGAL communities, METABOLITES, BACTERIAL population
Abstract

Pine wood nematode, Bursaphelenchus xylophilus, is a worldwide pest of pine trees, spreading at an alarming rate and with great ecological adaptability. In the process of causing disease, the nematode causes metabolic disorders and changes in the endophytic microbial community of the pine tree. However, the changes at the pine nidus during early nematode invasion have not been well studied, especially the differential metabolites, in Pinus massoniana, the main host of B. xylophilus in China. In this study, we analyzed the endophytic bacterial and fungal communities associated with healthy and B. xylophilus-caused wilted pine trees. The results show that 1333 bacterial OTUs and 502 fungal OTUs were annotated from P. massoniana stem samples. The abundance of bacterial communities in pine trees varies more following infection by B. xylophilus, but the abundance changes of fungal communities are less visible. There were significant differences in endophytic microbial diversity between wilted and healthy P. massoniana. In wilted pine trees, Actinobacteria and Bacteroidia were differential indicators of bacterial communities, whereas, in healthy pine trees, Rhizobiales in the Proteobacteria phylum were the major markers of bacterial communities. Meanwhile, the differential markers of fungal communities in healthy pines are Malasseziales, Tremellales, Sordariales, and Fusarium, whereas Pleosporaceae is the key marker of fungal communities in wilted pines. Our study examines the effect of changes in the endophytic microbial community on the health of pine trees that may be caused by B. xylophilus infection. In parallel, a non-targeted metabolomic study based on liquid mass spectrometry (LC-MS) technology was conducted on pine trees inoculated with pine nematodes and healthy pine trees with a view to identifying key compounds affecting early pine lesions. Ultimately, 307 distinctly different metabolites were identified. Among them, the riboflavin metabolic pathway in pine trees may play a key role in the early pathogenesis of pine wood nematode disease. [ABSTRACT FROM AUTHOR]

Published
2022
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5. Identification of the Extracellular Nuclease Influencing Soaking RNA Interference Efficiency in Bursaphelenchus xylophilus.

Author

Wang, Ruijiong, Li, Yongxia, Li, Dongzhen, Zhang, Wei, Wang, Xuan, Wen, Xiaojian, Liu, Zhenkai, Feng, Yuqian, and Zhang, Xingyao

Subjects
PINEWOOD nematode, RNA, GENE expression, DOUBLE-stranded RNA, GENE silencing, NUCLEASES
Abstract

RNA interference (RNAi) efficiency dramatically varies among different nematodes, which impacts research on their gene function and pest control. Bursaphelenchus xylophilus is a pine wood nematode in which RNAi-mediated gene silencing has unstable interference efficiency through soaking in dsRNA solutions, the factors of which remain unknown. Using agarose gel electrophoresis, we found that dsRNA can be degraded by nematode secretions in the soaking system which is responsible for the low RNAi efficiency. Based on the previously published genome and secretome data of B. xylophilus, 154 nucleases were screened including 11 extracellular nucleases which are potential factors reducing RNAi efficacy. To confirm the function of nucleases in RNAi efficiency, eight extracellular nuclease genes (BxyNuc1-8) were cloned in the genome. BxyNuc4, BxyNuc6 and BxyNuc7 can be upregulated in response to dsGFP, considered as the major nuclease performing dsRNA degradation. After soaking with the dsRNA of nucleases BxyNuc4/BxyNuc6/BxyNuc7 and Pat10 gene (ineffective in RNAi) simultaneously for 24 h, the expression of Pat10 gene decreased by 23.25%, 26.05% and 11.29%, respectively. With soaking for 36 h, the expression of Pat10 gene decreased by 43.25% and 33.25% in dsBxyNuc6+dsPat10 and dsBxyNuc7+dsPat10 groups, respectively. However, without dsPat10, dsBxyNuc7 alone could cause downregulation of Pat10 gene expression, while dsBxyNuc6 could not disturb this gene. In conclusion, the nuclease BxyNuc6 might be a major barrier to the RNAi efficiency in B. xylophilus. [ABSTRACT FROM AUTHOR]

Published
2022
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6. Transcriptome Analysis of Dauer Moulting of a Plant Parasitic Nematode, Bursaphelenchus xylophilus Promoted by Pine Volatile β-Pinene.

Author

Zhang, Wei, Li, Yongxia, Liu, Zhenkai, Li, Dongzhen, Wen, Xiaojian, Feng, Yuqian, Wang, Xuan, and Zhang, Xingyao

Subjects
PINEWOOD nematode, MOLTING, CONIFER wilt, PARASITIC plants, CYSTATHIONINE gamma-lyase, LIFE cycles (Biology), METABOLIC regulation
Abstract

Pinewood nematode, Bursaphelenchus xylophilus, a pine-parasitic nematode, poses a serious threat to pine trees globally, causing pine wilt disease. When dispersal-stage juvenile 4 (dauer, JIV, a durable stage) of B. xylophilus enters the new pine, it transforms into a propagative adult (dauer moulting) and reproduces quickly. Our previous studies have found that pine-volatile β-pinene promotes dauer moulting of B. xylophilus; however, this mechanism is not clear. Here, this study is attempting to unravel the molecular process underlying dauer moulting of B. xylophilus through signal chemical tests and transcriptome analysis. The results showed that β-pinene could promote dauer moulting of B. xylophilus, while other common dauer moulting signals, such as dafachronic acid (DA), part of the TGF/insulin signal pathway, were inoperative. Moreover, the JIV soaked in 1% β-pinene for only 6 h could transform into adults at a significant rate. Therefore, the transcriptomes of JIV soaked in 1% β-pinene for 6 h were sequenced. It was found that 15,556 genes were expressed; however, only 156 genes were expressed differentially and enriched in the metabolism of xenobiotics, peroxisome, fatty acid metabolism, and carbon metabolism, indicating that energy metabolism was active at the early stage of dauer moulting. With a stricter parameter, the number of differential genes fell to 19, including 4 sterol hydroxylase, 5 dehydrogenase, 2 glucuronosyltransferase, 5 nuclear-related factor, 1 calcium-binding protein, 1 nitrogen metabolic regulation protein, and 1 cystathionine gamma-lyase. These results indicated that dauer moulting of B. xylophilus into adults might not be regulated by the TGF-β/insulin signal pathway but by another new signal pathway related to the 19 differential genes which need more exploration. Our results contribute to the understanding of the molecular mechanisms behind dauer moulting and may be useful in reducing pine wilt disease by suppressing this moulting to cut the life cycle of B. xylophilus. [ABSTRACT FROM AUTHOR]

Published
2022
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