代谢互作模型再现叶片微生物组生态学。

Metabolic interaction models recapitulate leaf microbiota ecology.

机构信息

Institute of Microbiology, ETH Zurich, Zurich, Switzerland.

Laboratory of Computational Systems Biotechnology, École Polytechnique Fédérale de Lausanne, EPFL, Lausanne, Switzerland.

出版信息

Science. 2023 Jul 7;381(6653):eadf5121. doi: 10.1126/science.adf5121.

DOI:10.1126/science.adf5121

PMID:37410834

Abstract

Resource allocation affects the structure of microbiomes, including those associated with living hosts. Understanding the degree to which this dependency determines interspecies interactions may advance efforts to control host-microbiome relationships. We combined synthetic community experiments with computational models to predict interaction outcomes between plant-associated bacteria. We mapped the metabolic capabilities of 224 leaf isolates from by assessing the growth of each strain on 45 environmentally relevant carbon sources in vitro. We used these data to build curated genome-scale metabolic models for all strains, which we combined to simulate >17,500 interactions. The models recapitulated outcomes observed in planta with >89% accuracy, highlighting the role of carbon utilization and the contributions of niche partitioning and cross-feeding in the assembly of leaf microbiomes.

摘要

资源分配会影响微生物组的结构，包括与活体宿主相关的微生物组。了解这种依赖性在多大程度上决定种间相互作用，可能有助于控制宿主-微生物组的关系。我们将合成群落实验与计算模型相结合，以预测植物相关细菌之间的相互作用结果。我们通过评估每个菌株在体外 45 种环境相关碳源上的生长情况，来绘制 224 株叶分离物的代谢能力图谱。我们使用这些数据为所有菌株构建了经过精心编辑的基因组规模代谢模型，然后将它们组合在一起，模拟了超过 17500 次相互作用。这些模型以超过 89%的准确率再现了在植物体内观察到的结果，突出了碳利用的作用以及生态位分割和交叉喂养在叶片微生物组组装中的作用。

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代谢互作模型再现叶片微生物组生态学。

Metabolic interaction models recapitulate leaf microbiota ecology.

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