Depletion of protective microbiota promotes the incidence of fruit disease

Xue Luo, Kai Sun, Hao-Ran Li, Xiang-Yu Zhang, Yi-Tong Pan, De-Lin Luo, Yi-Bo Wu, Hui-Jun Jiang, Xiao-Han Wu, Chen-Yu Ma, Chuan-Chao Dai, Wei Zhang
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Abstract

Plant-associated microbiomes play important roles in plant health and productivity. However, despite fruits being directly linked to plant productivity, little is known about the microbiomes of fruits and their potential association with fruit health. Here, by integrating 16S rRNA gene, ITS high-throughput sequencing data and microbiological culturable approaches, we reported that roots and fruits (pods) of peanut, a typical plant that bears fruits underground, recruit different bacterial and fungal communities independently of cropping conditions, and that the incidence of pod disease under monocropping conditions is attributed to the depletion of Bacillus genus and enrichment of Aspergillus genus in geocarposphere. On this basis, we constructed a synthetic community (SynCom) consisting of three Bacillus strains from geocarposphere soil under rotation conditions with high culturable abundance. Comparative transcriptome, microbiome profiling and plant phytohormone signaling analysis reveal that the SynCom exhibited more effective Aspergillus growth inhibition and pod disease control than individual strain, which was underpinned by a combination of molecular mechanisms related to fungal cell proliferation interference, mycotoxins biosynthesis impairment and jasmonic acid-mediated plant immunity activation. Overall, our results reveal the filter effect of plant organs on the microbiome, and that depletion of key protective microbial community promotes the fruit disease incidence.
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保护性微生物群的减少会促进水果疾病的发生
植物相关微生物组在植物健康和生产力方面发挥着重要作用。然而,尽管水果与植物生产力直接相关,但人们对水果的微生物组及其与水果健康的潜在关联却知之甚少。在这里,通过整合 16S rRNA 基因、ITS 高通量测序数据和微生物培养方法,我们报道了花生这种典型的地下结果植物的根系和果实(荚果)会招募不同的细菌和真菌群落,而不受种植条件的影响,单一种植条件下荚果病害的发生归因于地果圈中枯草芽孢杆菌属的减少和曲霉属的富集。在此基础上,我们构建了一个合成群落(SynCom),由轮作条件下地果圈土壤中可培养丰度较高的三个芽孢杆菌菌株组成。通过比较转录组、微生物组剖析和植物植物激素信号分析发现,与单个菌株相比,SynCom 能更有效地抑制曲霉菌生长和控制豆荚病害,而这是由真菌细胞增殖干扰、霉菌毒素生物合成障碍和茉莉酸介导的植物免疫激活等分子机制共同作用的结果。总之,我们的研究结果揭示了植物器官对微生物群的过滤效应,关键保护性微生物群落的耗竭会促进果实病害的发生。
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