A simplified synthetic community from the healthy watermelon rhizosphere effectively mitigates Fusarium wilt.

IF 3.8 1区农林科学 Q1 AGRONOMY

Pest Management Science Pub Date : 2025-09-03 DOI:10.1002/ps.70193

Hongfeng Yu, Zhigang Wang, Renmao Tian, Weihui Xu

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引用次数: 0

Abstract

Background: Watermelon production is threatened by Fusarium oxysporum f. sp. niveum (Fon) in continuous cropping systems. Plant-recruited protective microbes can be assembled into synthetic communities to combat infections caused by Fon. The objective of this project was to assemble a simplified synthetic community for use in controlling Fusarium wilt in watermelon.

Results: The Shannon diversity of the bacterial community in the roots and rhizosphere of healthy watermelon plants was significantly higher than that of diseased plants. Under Fon challenge, healthy watermelon plants recruited certain beneficial bacteria taxa, such as Lysobacter, Microbacterium, Nocardioides and Sphingobium to the rhizosphere and roots. We identified the top ten bacterial genera enriched in the rhizosphere of healthy watermelon plants and utilized them to construct a disease-resistant synthetic community (SynCom I). After the joint selection of plants and pathogens, the synthetic community (SynCom I) containing ten bacteria was further simplified into a five-species community comprising Bacillus methylotrophicus J4, Agromyces mediolanus L1P43F5, Microbacterium maritypicum L2P04F12, Sphingobium mellinum L2P11G4 and Chryseobacterium lactis L1P41C5. The simplified synthetic community demonstrated a control efficacy of 99.6%, and the five-species members presented a cross-feeding interaction model. Removal of any one of B. methylotrophicus J4, Chryseobacterium lactis L1P41C5 and Sphingobium mellinum L2P11G4 led to an increase in the incidence rate compared with the synthetic community. In addition, B. methylotrophicus J4 and Chryseobacterium lactis L1P41C5 significantly promoted plant growth.

Conclusion: Our findings indicate that specific bacterial taxa enriched in the rhizosphere of healthy plants are correlated with enhanced disease resistance. Consequently, the construction and simplification of synthetic communities observed in this study may represent a strategy utilized by plants to mitigate the impact of Fusarium oxysporum f. sp. niveum. © 2025 Society of Chemical Industry.

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健康西瓜根际简易合成菌群可有效防治枯萎病。

背景：西瓜连作系统受到尖孢镰刀菌（Fusarium oxysporum f. sp. niveum, Fon）的威胁。植物招募的保护性微生物可以组装成合成群落来对抗由Fon引起的感染。本项目的目的是构建一个用于控制西瓜枯萎病的简易合成菌群。结果：西瓜健康植株根际和根际细菌群落Shannon多样性显著高于患病植株。在Fon胁迫下，健康西瓜植株向根际和根系吸收溶菌、微菌、拟诺卡菌和鞘菌等有益菌群。本研究鉴定了西瓜健康植株根际最富集的10个细菌属，并利用它们构建了一个抗病合成群落（SynCom I）。经过植物和病原菌的联合筛选，将含有10种细菌的合成菌群（SynCom I）进一步简化为由甲基营养芽孢杆菌J4、中绿农杆菌L1P43F5、海洋微杆菌L2P04F12、黄鞘菌L2P11G4和乳黄杆菌L1P41C5组成的5种菌群。简化后的合成群落防治效果为99.6%，5种成员呈交叉取食互作模式。与合成菌群相比，去除甲基营养菌B. J4、乳酸黄杆菌L1P41C5和黄颡鱼鞘菌L2P11G4中的任何一个都导致发病率增加。此外，甲基营养菌B. J4和乳黄杆菌L1P41C5显著促进植物生长。结论：健康植物根际中富集的特定细菌类群与抗病性增强有关。因此，本研究中观察到的合成群落的构建和简化可能是植物减轻尖孢镰刀菌影响的一种策略。©2025化学工业协会。

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来源期刊

Pest Management Science 农林科学-昆虫学

CiteScore

7.90

自引率

9.80%

发文量

553

审稿时长

4.8 months

期刊介绍： Pest Management Science is the international journal of research and development in crop protection and pest control. Since its launch in 1970, the journal has become the premier forum for papers on the discovery, application, and impact on the environment of products and strategies designed for pest management. Published for SCI by John Wiley & Sons Ltd.