In silico analysis and comparison of the metabolic capabilities of different organisms by reducing metabolic complexity.

IF 12.7 1区生物学 Q1 MICROBIOLOGY

Microbiome Pub Date : 2026-02-03 DOI:10.1186/s40168-025-02299-0

Evangelia Vayena, Meriç Ataman, Vassily Hatzimanikatis

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引用次数: 0

Abstract

Background: Understanding how metabolic capabilities diverge across microbial species is essential for deciphering community function, ecological interactions, and the design of synthetic microbiomes. Despite shared core pathways, microbial phenotypes can differ markedly due to evolutionary adaptations and metabolic specialization. Genome-scale metabolic models (GEMs) provide a systems-level framework to explore these differences; however, their complexity hinders direct comparison.

Results: We introduce NIS (Neidhardt-Ingraham-Schaechter), a computational workflow that integrates the redGEM, lumpGEM, and redGEMX algorithms to systematically reduce genome-scale models into biologically interpretable modules. This approach enables direct, quantitative comparison of fueling pathways, biomass biosynthetic routes, and environmental exchange processes while retaining essential metabolic information. We first demonstrate the utility of NIS by analyzing Escherichia coli and Saccharomyces cerevisiae, which revealed both conserved and divergent strategies in central metabolism, biosynthetic cost, and substrate utilization. We then applied NIS to the core honeybee gut microbiome, uncovering distinct metabolic traits, functional redundancy, and complementarity that help explain auxotrophy, cross-feeding interactions, and microbial coexistence.

Conclusions: NIS provides an automated, scalable, and reproducible framework for dissecting microbial metabolic networks beyond gene content or taxonomy. By linking metabolism to ecological function, NIS offers new opportunities to interpret microbial community dynamics and to support the rational design of microbiomes in health, agriculture, and environmental applications. Video Abstract.

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通过降低代谢复杂性对不同生物体的代谢能力进行计算机分析和比较。

背景：了解不同微生物物种的代谢能力是如何分化的，对于破译群落功能、生态相互作用和合成微生物组的设计至关重要。尽管有共同的核心途径，但由于进化适应和代谢专门化，微生物表型可能显着不同。基因组尺度代谢模型（GEMs）提供了一个系统级框架来探索这些差异；然而，它们的复杂性阻碍了直接比较。结果：我们引入了NIS (Neidhardt-Ingraham-Schaechter)，这是一个集成了redGEM、lumpGEM和redGEMX算法的计算工作流，可以系统地将基因组尺度模型简化为生物可解释的模块。这种方法可以在保留基本代谢信息的同时，对燃料途径、生物质生物合成途径和环境交换过程进行直接、定量的比较。我们首先通过分析大肠杆菌和酿酒酵母来证明NIS的实用性，揭示了它们在中心代谢、生物合成成本和底物利用方面的保守和不同策略。然后，我们将NIS应用于核心蜜蜂肠道微生物组，发现了不同的代谢特征、功能冗余和互补性，有助于解释营养不良、交叉摄食相互作用和微生物共存。结论：NIS提供了一个自动化的、可扩展的、可重复的框架，用于剖析基因内容或分类之外的微生物代谢网络。通过将代谢与生态功能联系起来，NIS为解释微生物群落动态和支持健康、农业和环境应用中微生物组的合理设计提供了新的机会。视频摘要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

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.