Towards applications of genome-scale metabolic model-based approaches in designing synthetic microbial communities

作     者：Huan Du Meng Li Yang Liu Huan Du;Meng Li;Yang Liu

作者机构：Archaeal Biology CenterInstitute for Advanced StudyShenzhen UniversityShenzhen 518060China Shenzhen Key Laboratory of Marine Microbiome EngineeringInstitute for Advanced StudyShenzhen UniversityShenzhen 18060China 

出 版 物：《Quantitative Biology》 (定量生物学（英文版）)

年 卷 期：2023年第11卷第1期

页      面：15-30页

核心收录：

学科分类：0710[理学-生物学] 07[理学] 071007[理学-遗传学] 

基　　金：the National Natural Science Foundation of China(Nos.92051102,32200099,32225003 and 31970105) the Innovation Team Project of Universities in Guangdong Province(No.2020KCXTD023) the Shenzhen Science and Technology Program(JCYJ20200109105010363). 

主　　题：genome-scale metabolic modeling microbial community design interspecies interaction environmental impact community-level performance 

摘      要：Background:Synthetic microbial communities,with different strains brought together by balancing their nutrition and promoting their interactions,demonstrate great advantages for exploring complex performance of communities and for further biotechnology applications.The potential of such microbial communities has not been explored,due to our limited knowledge of the extremely complex microbial interactions that are involved in designing and controlling effective and stable communities.Results:Genome-scale metabolic models(GEM)have been demonstrated as an effective tool for predicting and guiding the investigation and design of microbial communities,since they can explicitly and efficiently predict the phenotype of organisms from their genotypic data and can be used to explore the molecular mechanisms of microbehabitats and microbe-microbe interactions.In this work,we reviewed two main categories of GEM-based approaches and three uses related to design of synthetic microbial communities:predicting multi-species interactions,exploring environmental impacts on microbial phenotypes,and optimizing community-level performance.Conclusions:Although at the infancy stage,GEM-based approaches exhibit an increasing scope of applications in designing synthetic microbial communities.Compared to other methods,especially the use of laboratory cultures,GEM-based approaches can greatly decrease the trial-and-error cost of various procedures for designing synthetic communities and improving their functionality,such as identifying community members,determining media composition,evaluating microbial interaction potential or selecting the best community configuration.Future efforts should be made to overcome the limitations of the approaches,ranging from quality control of GEM reconstructions to community-level modeling algorithms,so that more applications of GEMs in studying phenotypes of microbial communities can be expected.