Antagonistic interactions between maize seeds microbiome species and the late wilt disease agent, Magnaporthiopsis maydis.

IF 2.1 Q3 MYCOLOGY
Frontiers in fungal biology Pub Date : 2024-08-07 eCollection Date: 2024-01-01 DOI:10.3389/ffunb.2024.1436759
Ofir Degani, Aseel Ayoub, Elhanan Dimant, Asaf Gordani
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Abstract

Magnaporthiopsis maydis is a maize pathogen that causes severe damage to commercial corn fields in the late growth stages. Late wilt disease (LWD) has spread since its discovery in the 1960s in Egypt and is now reported in about 10 countries. The pathogen has a hidden endophytic lifecycle in resistant corn plants and secondary hosts such as green foxtail, watermelon lupin and cotton. At the same time, it could be an opportunist and hinder the host development under the right conditions. This study uncovered M. maydis interactions with newly identified maize endophytes. To this end, six fungi were isolated from the seeds of three sweet corn cultivars having varying susceptibility to LWD. These isolates were identified using colony morphology and microscopic characterization, universal internal transcribed spacer (ITS) molecular targeting and phylogenetic analysis. Most of them belonged to pathogenic species. Compared to three previously identified bioprotective microorganisms, the new species were tested for their ability to secrete metabolites that repress M. maydis in vitro and to antagonize it in a solid media confront test and a seedlings pathogenicity assay. The opportunistic fungal species Aspergillus flavus (ME1), Aspergillus terreus (PE3) and the reference biocontrol bacteria Bacillus subtilis (R2) achieved the highest M. maydis inhibition degree in the plates tests (74-100% inhibition). The seedlings' pathogenicity assay that predicts the seeds' microflora resistance to M. maydis highlighted the bio-shielding potential of most species (23% or more epicotyl elongation over the infected control). Fusarium sp. (ME2) was the leading species in this measure (43% enhancement), and B. subtilis gave the best protection in terms of seeds' germination (50%) and sprouts' biomass (34%). The results of this study could enhance our understanding of the pathobiome's role in the context of LWD and represent a first step in using the seeds' natural protective microflora to develop novel management strategies.

玉米种子微生物组物种与晚疫病病原体 Magnaporthiopsis maydis 之间的拮抗相互作用。
Magnaporthiopsis maydis 是一种玉米病原体,会在玉米生长后期对商品玉米田造成严重破坏。自 20 世纪 60 年代在埃及发现以来,晚疫病(LWD)已经蔓延开来,现在大约有 10 个国家都有报道。病原体在抗性玉米植株和次要寄主(如绿狐尾、西瓜羽扇豆和棉花)中具有隐蔽的内生生命周期。同时,它也可能是机会主义者,在适当的条件下阻碍寄主的发展。本研究揭示了 M. maydis 与新发现的玉米内生菌之间的相互作用。为此,我们从对 LWD 敏感性不同的三个甜玉米栽培品种的种子中分离出了六种真菌。利用菌落形态和显微特征、通用内部转录间隔(ITS)分子定位和系统发育分析对这些分离物进行了鉴定。其中大部分属于致病物种。与之前发现的三种生物保护性微生物相比,新菌种在体外分泌代谢物抑制 M. maydis 的能力以及在固体培养基对抗试验和幼苗致病性试验中拮抗 M. maydis 的能力得到了检验。在平板试验中,机会真菌黄曲霉(ME1)、赤曲霉(PE3)和参考生防菌枯草芽孢杆菌(R2)对麦地那龙线虫的抑制率最高(74%-100%)。秧苗致病性检测可预测种子微生物菌群对麦地那龙线虫的抗性,该检测强调了大多数物种的生物屏蔽潜力(外胚轴伸长率比受感染的对照高 23% 或更多)。镰刀菌(ME2)在这一指标中居首位(提高 43%),而枯草芽孢杆菌则在种子发芽率(50%)和萌芽生物量(34%)方面提供了最佳保护。这项研究的结果可以加深我们对病原生物群在LWD中的作用的理解,并为利用种子的天然保护性微生物群来制定新型管理策略迈出了第一步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
2.70
自引率
0.00%
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审稿时长
13 weeks
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