Cover crop root exudates impact soil microbiome functional trajectories in agricultural soils.

IF 13.8 1区 生物学 Q1 MICROBIOLOGY Microbiome Pub Date : 2024-09-28 DOI:10.1186/s40168-024-01886-x
Valerie A Seitz, Bridget B McGivern, Mikayla A Borton, Jacqueline M Chaparro, Meagan E Schipanski, Jessica E Prenni, Kelly C Wrighton
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Abstract

Background: Cover cropping is an agricultural practice that uses secondary crops to support the growth of primary crops through various mechanisms including erosion control, weed suppression, nutrient management, and enhanced biodiversity. Cover crops may elicit some of these ecosystem services through chemical interactions with the soil microbiome via root exudation, or the release of plant metabolites from roots. Phytohormones are one metabolite type exuded by plants that activate the rhizosphere microbiome, yet managing this chemical interaction remains an untapped mechanism for optimizing plant-soil-microbiome interactions. Currently, there is limited understanding on the diversity of cover crop phytohormone root exudation patterns and our aim was to understand how phytochemical signals selectively enrich specific microbial taxa and functionalities in agricultural soils.

Results: Here, we link variability in cover crop root exudate composition to changes in soil microbiome functionality. Exudate chemical profiles from 4 cover crop species (Sorghum bicolor, Vicia villosa, Brassica napus, and Secale cereal) were used as the chemical inputs to decipher microbial responses. These distinct exudate profiles, along with a no exudate control, were amended to agricultural soil microcosms with microbial responses tracked over time using metabolomes and genome-resolved metatranscriptomes. Our findings illustrated microbial metabolic patterns were unique in response to cover crop exudate inputs over time, particularly by sorghum and cereal rye amended microcosms. In these microcosms, we identify novel microbial members (at the genera and family level) who produced IAA and GA4 over time. Additionally, we identified cover crop exudates exclusively enriched for bacterial nitrite oxidizers, while control microcosms were discriminated for nitrogen transport, mineralization, and assimilation, highlighting distinct changes in microbial nitrogen cycling in response to chemical inputs.

Conclusions: We highlight that root exudate amendments alter microbial community function (i.e., N cycling) and microbial phytohormone metabolisms, particularly in response to root exudates isolated from cereal rye and sorghum plants. Additionally, we constructed a soil microbial genomic catalog of microorganisms responding to commonly used cover crops, a public resource for agriculturally relevant microbes. Many of our exudate-stimulated microorganisms are representatives from poorly characterized or novel taxa, revealing the yet to be discovered metabolic reservoir harbored in agricultural soils. Our findings emphasize the tractability of high-resolution multi-omics approaches to investigate processes relevant for agricultural soils, opening the possibility of targeting specific soil biogeochemical outcomes through biological precision agricultural practices that use cover crops and the microbiome as levers for enhanced crop production. Video Abstract.

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覆盖作物根部渗出物影响农田土壤微生物组的功能轨迹。
背景:覆盖种植是一种农业耕作方法,它利用副作物通过各种机制支持主作物的生长,包括侵蚀控制、杂草抑制、养分管理和增强生物多样性。覆盖作物可通过根系渗出或从根部释放植物代谢物与土壤微生物群发生化学作用,从而提供其中一些生态系统服务。植物激素是植物渗出的一种代谢物,可激活根圈微生物群,但管理这种化学相互作用仍是优化植物-土壤-微生物群相互作用的一个尚未开发的机制。目前,人们对覆盖作物植物激素根渗出模式多样性的了解有限,我们的目的是了解植物化学信号如何选择性地丰富农业土壤中的特定微生物类群和功能:结果:在这里,我们将覆盖作物根系渗出物成分的变化与土壤微生物组功能的变化联系起来。来自 4 种覆盖作物(高粱、紫花地丁、芸苔属和山苍子)的渗出物化学特征被用作解读微生物反应的化学输入。这些不同的渗出物以及无渗出物对照被添加到农业土壤微生态系统中,并利用代谢组和基因组解析的元转录组跟踪微生物随时间变化的反应。我们的研究结果表明,随着时间的推移,微生物代谢模式对覆盖作物渗出物输入的反应是独特的,尤其是高粱和黑麦微生态系统。在这些微生态系统中,我们发现了随着时间推移产生 IAA 和 GA4 的新型微生物成员(属和科一级)。此外,我们还发现覆盖作物渗出物专门富含亚硝酸细菌氧化剂,而对照微生态系统则在氮输送、矿化和同化方面有所区别,这突出表明了微生物氮循环在响应化学投入方面的独特变化:我们强调,根渗出物添加剂改变了微生物群落功能(即氮循环)和微生物植物激素代谢,尤其是对从黑麦和高粱植物中分离出来的根渗出物的反应。此外,我们还构建了一个土壤微生物基因组目录,其中包含了对常用覆盖作物做出反应的微生物,这是农业相关微生物的公共资源。我们的许多受渗出物刺激的微生物都是特征不明显或新型类群的代表,揭示了农业土壤中尚未被发现的代谢库。我们的发现强调了高分辨率多组学方法在研究农业土壤相关过程中的可操作性,为通过生物精准农业实践瞄准特定的土壤生物地球化学结果提供了可能性,这些实践利用覆盖作物和微生物组作为提高作物产量的杠杆。视频摘要。
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来源期刊
Microbiome
Microbiome MICROBIOLOGY-
CiteScore
21.90
自引率
2.60%
发文量
198
审稿时长
4 weeks
期刊介绍: Microbiome is a journal that focuses on studies of microbiomes in humans, animals, plants, and the environment. It covers both natural and manipulated microbiomes, such as those in agriculture. The journal is interested in research that uses meta-omics approaches or novel bioinformatics tools and emphasizes the community/host interaction and structure-function relationship within the microbiome. Studies that go beyond descriptive omics surveys and include experimental or theoretical approaches will be considered for publication. The journal also encourages research that establishes cause and effect relationships and supports proposed microbiome functions. However, studies of individual microbial isolates/species without exploring their impact on the host or the complex microbiome structures and functions will not be considered for publication. Microbiome is indexed in BIOSIS, Current Contents, DOAJ, Embase, MEDLINE, PubMed, PubMed Central, and Science Citations Index Expanded.
期刊最新文献
Ileal microbial microbiome and its secondary bile acids modulate susceptibility to nonalcoholic steatohepatitis in dairy goats. The links between dietary diversity and RNA virus diversity harbored by the great evening bat (Ia io). From grasslands to genes: exploring the major microbial drivers of antibiotic-resistance in microhabitats under persistent overgrazing. Correction: Parabacteroides distasonis regulates the infectivity and pathogenicity of SVCV at different water temperatures. The intestinal microbiome and Cetobacterium somerae inhibit viral infection through TLR2-type I IFN signaling axis in zebrafish.
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