茶树叶际微生物群的时间代谢响应促进对真菌病原体的持续抑制。
Temporal metabolite responsiveness of microbiota in the tea plant phyllosphere promotes continuous suppression of fungal pathogens.
机构信息
College of Agriculture and Biotechnology, Zhejiang University, Hangzhou 310058, China; Key Laboratory of Horticultural Plant Growth, Development and Quality Improvement, Ministry of Agriculture, Zhejiang University, Hangzhou 310058, China.
College of Agriculture and Biotechnology, Zhejiang University, Hangzhou 310058, China; Key Laboratory of Biology of Crop Pathogens and Insects of Zhejiang Province, Key Laboratory of Molecular Biology of Crop Pathogens and Insects, Ministry of Agriculture, Zhejiang University, Hangzhou 310058, China; Institute of Environmental Biotechnology, Graz University of Technology, Petersgasse 12, 8010 Graz, Austria.
出版信息
J Adv Res. 2022 Jul;39:49-60. doi: 10.1016/j.jare.2021.10.003. Epub 2021 Oct 18.
INTRODUCTION
A broad spectrum of rhizosphere bacteria and fungi were shown to play a central role for health, fitness and productivity of their host plants. However, implications of host metabolism on microbiota assembly in the phyllosphere and potential consequences for holobiont functioning were sparsely addressed. Previous observations indicated that tea plants might reduce disease occurrence in various forests located in their proximity; the underlying mechanisms and potential implications of the phyllosphere microbiota remained elusive.
OBJECTIVES
This study aimed atdeciphering microbiome assembly in the tea plant phyllosphere throughout shoot development as well as elucidating potential implications of host metabolites in this process. The main focus was to explore hidden interconnections between the homeostasis of the phyllosphere microbiome and resistance to fungal pathogens.
METHODS
Profiling of host metabolites and microbiome analyses based on high-throughput sequencing were integrated to identify drivers of microbiome assembly throughout shoot development in the phyllosphere of tea plants. This was complemented by tracking of beneficial microorganisms in all compartments of the plant. Synthetic assemblages (SynAss), bioassays and field surveys were implemented to verify functioning of the phyllosphere microbiota.
RESULTS
Theophylline and epigallocatechin gallate, two prevalent metabolites at the early and late shoot development stage respectively, were identified as the main drivers of microbial community assembly. Flavobacterium and Myriangium were distinct microbial responders at the early stage, while Parabacteroides and Mortierella were more enriched at the late stage. Reconstructed, stage-specific SynAss suppressed various tree phytopathogens by 13.0%-69.3% in vitro and reduced disease incidence by 8.24%-41.3% in vivo.
CONCLUSION
The findings indicate that a functional phyllosphere microbiota was assembled along with development-specific metabolites in tea plants, which continuously suppressed prevalent fungal pathogens. The insights gained into the temporally resolved metabolite response of the tea plant microbiota could provide novel solutions for disease management.
简介
大量的根际细菌和真菌被证明在宿主植物的健康、适应能力和生产力方面发挥着核心作用。然而,宿主代谢对叶片微生物区系组装的影响以及对整个共生体功能的潜在后果还鲜有研究。先前的研究表明,茶树可能会降低其周围各种森林中疾病的发生频率;叶片微生物区系的潜在机制和潜在影响仍然难以捉摸。
目的
本研究旨在解析茶树叶片在整个新梢发育过程中的微生物组组装,阐明宿主代谢物在这一过程中的潜在影响。主要焦点是探索叶片微生物区系的内稳态与抗真菌病原体之间的隐藏关联。
方法
基于高通量测序的宿主代谢物和微生物组分析相结合,以鉴定茶树叶片微生物组在新梢发育过程中的组装驱动因素。同时,跟踪植物所有部位的有益微生物。通过合成组装(SynAss)、生物测定和野外调查来验证叶片微生物区系的功能。
结果
茶碱和表没食子儿茶素没食子酸酯分别是新梢早期和晚期发育阶段的主要代谢物,被鉴定为微生物群落组装的主要驱动因素。黄杆菌属和微单胞菌属是早期的明显微生物响应者,而拟杆菌属和白僵菌属在晚期更为丰富。重建的、特定于阶段的 SynAss 在体外抑制各种树木病原菌的活性为 13.0%-69.3%,在体内降低疾病发病率为 8.24%-41.3%。
结论
研究结果表明,茶树中功能性叶片微生物区系是沿着发育特异性代谢物组装的,这些代谢物持续抑制着普遍存在的真菌病原体。深入了解茶树微生物区系的时间分辨代谢物响应,可以为疾病管理提供新的解决方案。
Zotero 插件