基因组规模的代谢模型一致地预测纹状体棒状杆菌的体外特征。

IF 2.8 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Frontiers in bioinformatics Pub Date : 2023-10-23 eCollection Date: 2023-01-01 DOI:10.3389/fbinf.2023.1214074
Famke Bäuerle, Gwendolyn O Döbel, Laura Camus, Simon Heilbronner, Andreas Dräger
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引用次数: 0

摘要

引言:基因组规模代谢模型(GEMs)是生物体特有的知识库,可用于揭示致病性或提高生物技术应用中特定代谢产物的产生。然而,在体外环境中预测细菌增殖的有效性几乎没有得到研究。方法:本工作结合了计算机和体外方法,创建和策划纹状体棒状杆菌的菌株特异性基因组级代谢模型。结果:我们介绍了五个新创建的高质量菌株特异性基因组规模代谢模型(GEM),满足所有当代标准和要求。所有这些模型都使用社区标准测试套件代谢模型测试(MEMOTE)进行了基准测试,并通过实验室实验进行了验证。为了管理这些模型,开发了软件基础设施精化GEM,以并行处理这些模型,并符合GEM的质量标准。实验数据证实了模型预测,并开发了一种基于倍增时间的新的比较指标来量化细菌生长。讨论:未来的建模项目可以依赖于所提出的软件,该软件独立于特定的环境条件。基于生长率计算的验证方法现在可以使用,并且与生物学问题密切相关。策划的模型可以通过BioModels和GitHub存储库免费获得,并且可以使用。开源软件精化GEMS可从https://github.com/draeger-lab/refinegems.
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Genome-scale metabolic models consistently predict in vitro characteristics of Corynebacterium striatum.

Introduction: Genome-scale metabolic models (GEMs) are organism-specific knowledge bases which can be used to unravel pathogenicity or improve production of specific metabolites in biotechnology applications. However, the validity of predictions for bacterial proliferation in in vitro settings is hardly investigated. Methods: The present work combines in silico and in vitro approaches to create and curate strain-specific genome-scale metabolic models of Corynebacterium striatum. Results: We introduce five newly created strain-specific genome-scale metabolic models (GEMs) of high quality, satisfying all contemporary standards and requirements. All these models have been benchmarked using the community standard test suite Metabolic Model Testing (MEMOTE) and were validated by laboratory experiments. For the curation of those models, the software infrastructure refineGEMs was developed to work on these models in parallel and to comply with the quality standards for GEMs. The model predictions were confirmed by experimental data and a new comparison metric based on the doubling time was developed to quantify bacterial growth. Discussion: Future modeling projects can rely on the proposed software, which is independent of specific environmental conditions. The validation approach based on the growth rate calculation is now accessible and closely aligned with biological questions. The curated models are freely available via BioModels and a GitHub repository and can be used. The open-source software refineGEMs is available from https://github.com/draeger-lab/refinegems.

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