Plant Sciences, School of Life Sciences, University of Dundeegrid.8241.f, Dundee, United Kingdom.
Agrobiosciences Program, Plant & Soil Microbiome Subprogram, Mohammed VI Polytechnic University, Benguerir, Morocco.
mSystems. 2022 Dec 20;7(6):e0093422. doi: 10.1128/msystems.00934-22. Epub 2022 Nov 7.
The microbiota populating the rhizosphere, the interface between roots and soil, can modulate plant growth, development, and health. These microbial communities are not stochastically assembled from the surrounding soil, but their composition and putative function are controlled, at least partially, by the host plant. Here, we use the staple cereal barley as a model to gain novel insights into the impact of differential applications of nitrogen, a rate-limiting step for global crop production, on the host genetic control of the rhizosphere microbiota. Using a high-throughput amplicon sequencing survey, we determined that nitrogen availability for plant uptake is a factor promoting the selective enrichment of individual taxa in the rhizosphere of wild and domesticated barley genotypes. Shotgun sequencing and metagenome-assembled genomes revealed that this taxonomic diversification is mirrored by a functional specialization, manifested by the differential enrichment of multiple Gene Ontology terms, of the microbiota of plants exposed to nitrogen conditions limiting barley growth. Finally, a plant soil feedback experiment revealed that host control of the barley microbiota underpins the assembly of a phylogenetically diverse group of bacteria putatively required to sustain plant performance under nitrogen-limiting supplies. Taken together, our observations indicate that under nitrogen conditions limiting plant growth, host-microbe and microbe-microbe interactions fine-tune the host genetic selection of the barley microbiota at both taxonomic and functional levels. The disruption of these recruitment cues negatively impacts plant growth. The microbiota inhabiting the rhizosphere, the thin layer of soil surrounding plant roots, can promote the growth, development, and health of their host plants. Previous research indicated that differences in the genetic composition of the host plant coincide with variations in the composition of the rhizosphere microbiota. This is particularly evident when looking at the microbiota associated with input-demanding modern cultivated varieties and their wild relatives, which have evolved under marginal conditions. However, the functional significance of these differences remains to be fully elucidated. We investigated the rhizosphere microbiota of wild and cultivated genotypes of the global crop barley and determined that nutrient conditions limiting plant growth amplify the host control on microbes at the root-soil interface. This is reflected in a plant- and genotype-dependent functional specialization of the rhizosphere microbiota, which appears to be required for optimal plant growth. These findings provide novel insights into the significance of the rhizosphere microbiota for plant growth and sustainable agriculture.
根际微生物群落栖息在根际,即根系与土壤之间的界面,它们可以调节植物的生长、发育和健康。这些微生物群落不是随机从周围土壤中组装而成的,而是其组成和潜在功能至少部分受到宿主植物的控制。在这里,我们以主要的谷物大麦为例,深入了解氮素(全球作物生产的限速步骤)的不同应用对根际微生物群落的宿主遗传控制的影响。通过高通量扩增子测序调查,我们发现植物可吸收氮素的可用性是促进个别分类群在野生和驯化大麦基因型根际选择性富集的因素。鸟枪法测序和宏基因组组装基因组揭示了这种分类多样性反映了功能专业化,表现在暴露于限制大麦生长的氮条件下的植物微生物群中,多个基因本体论术语的差异富集。最后,一项植物-土壤反馈实验表明,宿主对大麦微生物群的控制是组装一个系统发育多样化的细菌群的基础,这些细菌群被认为是在氮素供应有限的情况下维持植物性能所必需的。总之,我们的观察结果表明,在限制植物生长的氮素条件下,宿主-微生物和微生物-微生物相互作用在分类和功能水平上微调了宿主对大麦微生物群的遗传选择。这些招募线索的中断会对植物生长产生负面影响。根际微生物群落栖息在植物根系周围的薄层土壤中,可以促进其宿主植物的生长、发育和健康。先前的研究表明,宿主植物遗传组成的差异与根际微生物群落组成的变化相吻合。这在与输入需求较高的现代栽培品种及其在边缘条件下进化的野生亲缘种相关的微生物群中尤为明显。然而,这些差异的功能意义仍有待充分阐明。我们研究了全球作物大麦的野生和栽培基因型的根际微生物群落,发现限制植物生长的营养条件放大了宿主对根-土界面微生物的控制。这反映在根际微生物群落的植物和基因型依赖性功能专业化上,这似乎是植物最佳生长所必需的。这些发现为根际微生物群落对植物生长和可持续农业的重要性提供了新的见解。
