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基于代谢建模的框架,用于预测作物植物天然根瘤菌中的营养依赖关系。

A metabolic modeling-based framework for predicting trophic dependencies in native rhizobiomes of crop plants.

机构信息

Department of Natural Resources, Newe Ya'ar Research Center, Agricultural Research Organization (Volcani Institute), Ramat Ishay, Israel.

Department of Plant Pathology and Microbiology, The Robert H. Smith Faculty of Agriculture, Food and Environment, The Hebrew University of Jerusalem, Rehovot, Israel.

出版信息

Elife. 2024 Oct 17;13:RP94558. doi: 10.7554/eLife.94558.

DOI:10.7554/eLife.94558
PMID:39417540
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11486489/
Abstract

The exchange of metabolites (i.e., metabolic interactions) between bacteria in the rhizosphere determines various plant-associated functions. Systematically understanding the metabolic interactions in the rhizosphere, as well as in other types of microbial communities, would open the door to the optimization of specific predefined functions of interest, and therefore to the harnessing of the functionality of various types of microbiomes. However, mechanistic knowledge regarding the gathering and interpretation of these interactions is limited. Here, we present a framework utilizing genomics and constraint-based modeling approaches, aiming to interpret the hierarchical trophic interactions in the soil environment. 243 genome scale metabolic models of bacteria associated with a specific disease-suppressive vs disease-conducive apple rhizospheres were drafted based on genome-resolved metagenomes, comprising an in silico native microbial community. Iteratively simulating microbial community members' growth in a metabolomics-based apple root-like environment produced novel data on potential trophic successions, used to form a network of communal trophic dependencies. Network-based analyses have characterized interactions associated with beneficial vs non-beneficial microbiome functioning, pinpointing specific compounds and microbial species as potential disease supporting and suppressing agents. This framework provides a means for capturing trophic interactions and formulating a range of testable hypotheses regarding the metabolic capabilities of microbial communities within their natural environment. Essentially, it can be applied to different environments and biological landscapes, elucidating the conditions for the targeted manipulation of various microbiomes, and the execution of countless predefined functions.

摘要

根际细菌之间的代谢物交换(即代谢相互作用)决定了各种与植物相关的功能。系统地了解根际以及其他类型微生物群落中的代谢相互作用,将为优化特定的预定义功能打开大门,从而利用各种类型微生物组的功能。然而,关于这些相互作用的收集和解释的机制知识有限。在这里,我们提出了一个利用基因组学和基于约束的建模方法的框架,旨在解释土壤环境中的层次化营养相互作用。根据基于基因组解析的宏基因组,为与特定的抑病与感病苹果根际相关的细菌制定了 243 个基于基因组的代谢模型,这些细菌包含了一个计算机原生微生物群落。在基于代谢组学的模拟苹果根环境中迭代模拟微生物群落成员的生长,产生了关于潜在营养成功的新数据,用于形成一个公共营养依赖关系网络。基于网络的分析已经描述了与有益和非有益微生物组功能相关的相互作用,确定了特定的化合物和微生物物种作为潜在的疾病支持和抑制因子。该框架提供了一种捕捉营养相互作用的方法,并提出了一系列可用于检验微生物群落在其自然环境中的代谢能力的假设。本质上,它可以应用于不同的环境和生物景观,阐明了针对各种微生物组进行有针对性的操纵的条件,以及执行无数预定义功能的条件。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/41eb/11486489/4f0592ea2643/elife-94558-fig6-figsupp1.jpg
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