Fine-scale characterization of the soybean rhizosphere microbiome via synthetic long reads and avidity sequencing.

IF 6.2 2区 环境科学与生态学 Q1 GENETICS & HEREDITY Environmental Microbiome Pub Date : 2024-07-12 DOI:10.1186/s40793-024-00590-5
Brett Hale, Caitlin Watts, Matthew Conatser, Edward Brown, Asela J Wijeratne
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Abstract

Background: The rhizosphere microbiome displays structural and functional dynamism driven by plant, microbial, and environmental factors. While such plasticity is a well-evidenced determinant of host health, individual and community-level microbial activity within the rhizosphere remain poorly understood, due in part to the insufficient taxonomic resolution achieved through traditional marker gene amplicon sequencing. This limitation necessitates more advanced approaches (e.g., long-read sequencing) to derive ecological inferences with practical application. To this end, the present study coupled synthetic long-read technology with avidity sequencing to investigate eukaryotic and prokaryotic microbiome dynamics within the soybean (Glycine max) rhizosphere under field conditions.

Results: Synthetic long-read sequencing permitted de novo reconstruction of the entire 18S-ITS1-ITS2 region of the eukaryotic rRNA operon as well as all nine hypervariable regions of the 16S rRNA gene. All full-length, mapped eukaryotic amplicon sequence variants displayed genus-level classification, and 44.77% achieved species-level classification. The resultant eukaryotic microbiome encompassed five kingdoms (19 genera) of protists in addition to fungi - a depth unattainable with conventional short-read methods. In the prokaryotic fraction, every full-length, mapped amplicon sequence variant was resolved at the species level, and 23.13% at the strain level. Thirteen species of Bradyrhizobium were thereby distinguished in the prokaryotic microbiome, with strain-level identification of the two Bradyrhizobium species most reported to nodulate soybean. Moreover, the applied methodology delineated structural and compositional dynamism in response to experimental parameters (i.e., growth stage, cultivar, and biostimulant application), unveiled a saprotroph-rich core microbiome, provided empirical evidence for host selection of mutualistic taxa, and identified key microbial co-occurrence network members likely associated with edaphic and agronomic properties.

Conclusions: This study is the first to combine synthetic long-read technology and avidity sequencing to profile both eukaryotic and prokaryotic fractions of a plant-associated microbiome. Findings herein provide an unparalleled taxonomic resolution of the soybean rhizosphere microbiota and represent significant biological and technological advancements in crop microbiome research.

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通过合成长读数和噬菌体测序对大豆根瘤微生物组进行精细表征。
背景:在植物、微生物和环境因素的驱动下,根瘤菌群显示出结构和功能的动态性。虽然这种可塑性是宿主健康的决定因素之一,但人们对根瘤菌圈中个体和群落水平的微生物活动仍然知之甚少,部分原因是传统的标记基因扩增片段测序无法实现足够的分类分辨率。这种局限性要求采用更先进的方法(如长线程测序)来得出具有实际应用价值的生态推论。为此,本研究将合成长读数技术与热敏测序技术相结合,研究了田间条件下大豆(Glycine max)根瘤菌群中真核微生物和原核微生物的动态变化:结果:合成长序列测序技术可以从头开始重建真核生物 rRNA 操作子的整个 18S-ITS1-ITS2 区域以及 16S rRNA 基因的全部 9 个超变区。所有绘制的全长真核生物扩增子序列变体都显示了属级分类,44.77%达到了种级分类。由此得出的真核微生物组除真菌外,还包括五大原生生物界(19 个属)--这是传统短读数方法无法达到的深度。在原核生物部分,每一个全长映射扩增片段序列变异都在物种水平上得到了解析,23.13%在菌株水平上得到了解析。因此,在原核微生物组中区分出了 13 个布拉迪根单胞菌物种,并在菌株水平上鉴定出了据报道最能使大豆结瘤的两个布拉迪根单胞菌物种。此外,所应用的方法还描述了结构和组成对实验参数(即生长阶段、栽培品种和生物刺激剂的应用)的动态响应,揭示了一个富含食液微生物的核心微生物组,为互生类群的宿主选择提供了经验证据,并确定了可能与环境和农艺特性相关的关键微生物共生网络成员:本研究首次将合成长读数技术和酶测序技术相结合,对植物相关微生物群的真核和原核部分进行了剖析。本文的研究结果为大豆根瘤微生物群提供了无与伦比的分类分辨率,代表了作物微生物群研究在生物学和技术方面的重大进展。
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来源期刊
Environmental Microbiome
Environmental Microbiome Immunology and Microbiology-Microbiology
CiteScore
7.40
自引率
2.50%
发文量
55
审稿时长
13 weeks
期刊介绍: Microorganisms, omnipresent across Earth's diverse environments, play a crucial role in adapting to external changes, influencing Earth's systems and cycles, and contributing significantly to agricultural practices. Through applied microbiology, they offer solutions to various everyday needs. Environmental Microbiome recognizes the universal presence and significance of microorganisms, inviting submissions that explore the diverse facets of environmental and applied microbiological research.
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