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病害侵染下茶树叶际微生物的响应OA

Response of Phyllosphere Microorganism in Tea Plants Under Disease Infection

中文摘要英文摘要

植物叶际微生物在植物抗病过程中发挥重要作用,但其在病害侵染下的响应机制仍需深入探究.以茶树品种'智仁早'为对象,通过分析叶际微生物群落结构及功能,揭示茶树叶际微生物对病害侵染的响应及其潜在的抗病机制.采集健康与感病茶树叶片,以基因高通量测序技术结合微生物组学等解析主要病原菌种类、细菌与真菌群落组成,并进行功能预测.结果表明,感病叶片A(IA)中以镰刀菌属(Fusarium)真菌为主要病原菌,而感病叶片B(IB)则以盘多毛孢属(Pestalotia)真菌为主;所有感病叶片的细菌和真菌α多样性均显著高于健康叶片(P<0.05),β多样性分析显示群落结构差异显著.在物种组成上,健康叶片细菌以变形菌门(Proteobacteria)为主,占比达79.9%,而感病叶片中以变形菌门(Proteobacteria)和放线菌门(Actinobacteria)为主;真菌群落中,座囊菌纲(Dothideomycetes)为共优势类群,但感病叶片中以粪壳菌纲(Sordariomycetes)、伞菌纲(Agaricomycetes)和散囊菌纲(Eurotiomycetes)为主.LEfSe分析进一步筛选出显著差异物种:健康叶片中毛球菌属(Trichococcus)、假单胞菌属(Pseudomonas)等潜在有益菌占优,而感病叶片中则以亚隔孢壳属(Didymella)、小不整球壳属(Plectosphaerella)、镰刀菌属、盘多毛孢属(Pestalotia)等致病菌为主.功能预测结果表明,健康叶片微生物功能集中于光合作用、碳固定等代谢通路,而感病叶片中细菌趋化性、鞭毛组装及丁酸盐代谢相关通路显著增强;此外,FUNGuild注释显示,感病叶片中植物病原菌、植物腐生菌与木材腐生菌比例增加,病害侵染或重塑茶树叶际微生物群落结构,病原菌的增殖与有益菌的减少可能共同影响茶树抗病能力.研究结果为解析叶际微生物在植物-病原互作中的作用提供了理论依据,并为茶树病害的生物防治策略开发奠定了科学基础.

Phyllosphere microorganism play a critical role in plant disease resistance,yet their response mechanisms under pathogen infection require further exploration.This study investigated the structural and functional dynamics of phyllosphere microbial communities in healthy and infected leaves of Camellia sinensis cv.'Zhirenzao'to elucidate their responses to pathogen invasion and potential roles in disease defense.In this study,we collected healthy and infected leaves,and analyzed them by high-throughput gene sequencing and microbiome analysis to identify primary pathogens,delineate bacterial and fungal community structures,and predict microbial functions.The results reveal that Fusarium and Pestalotia were the dominant pathogenic genera in the infected leaves A(IA)and B(IB),respectively.Both bacterial and fungal α-diversity were significantly higher in the infected leaves compared to those of healthy leaves(P<0.05),and the β-diversity analysis also reveals significant structural differences.In terms of species composition,the healthy leaves were dominated by Proteobacteria(79.9%),while the infected leaves were mainly composed of both Proteobacteria and Actinobacteria.Within the fungal communities,Dothideomycetes was a co-dominant class,while the infected leaves were dominated by Sordariomycetes,Agaricomycetes and Eurotiomycetes.LEfSe analysis further identified the significant differentiating species:the healthy leaves were dominated by potentially beneficial microbes like Trichococcus and Pseudomonas,whereas the infected leaves were primarily composed of pathogenic genera including Didymella,Plectosphaerella,Fusarium and Pestalotia.The results from functional prediction demonstrate that microbial functions in the healthy leaves were enriched for photosynthesis and carbon fixation pathways,while the infected leaves exhibited significant increase in pathways for bacterial chemotaxis,flagellar assembly and butyrate metabolism.FUNGuild annotation further reveals an increase in the proportion of plant pathogens,plant saprotrophs and wood saprotrophs in the diseased leaves,potentially reshaping the phyllosphere microbial community,where the proliferation of pathogens and decline of beneficial microbes may collectively impair host resistance.These findings provide a theoretical framework for understanding phyllosphere microbial functions in plant-pathogen interactions and establish a scientific basis for developing biocontrol strategies against tea plant diseases.

叶诚诚;吴秀云;李紫成;吴碎典;金山发;朱洁

温州市植物保护与土壤肥料管理站,浙江温州 325000乐清市农业农村局,浙江乐清 325600温州市植物保护与土壤肥料管理站,浙江温州 325000泰顺县茶产业发展中心,浙江泰顺 325500乐清市雁荡山茶场,浙江乐清 325600温州市植物保护与土壤肥料管理站,浙江温州 325000

农业科技

茶树叶际微生物高通量测序功能预测

Camellia sinensisphyllosphere microorganismhigh-throughput sequencingfunctional prediction

《茶叶科学》 2026 (2)

279-291,13

浙江省农业产业技术推广服务团队项目

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