生物
微生物群
计算生物学
代谢网络
成对比较
粪肠球菌
细菌
群落结构
生物技术
微生物学
遗传学
生态学
计算机科学
人工智能
金黄色葡萄球菌
作者
Anna S. Weiß,Anna Burrichter,Abilash Chakravarthy Durai Raj,Alexandra von Strempel,Chen Meng,Karin Kleigrewe,Philipp C. Münch,Luis Rössler,Claudia Huber,Wolfgang Eisenreich,Lara M. Jochum,Stephanie Göing,Kirsten Jung,Chiara Lincetto,Johannes Hübner,Γεώργιος Μαρίνος,Johannes Zimmermann,Christoph Kaleta,Álvaro Sánchez,Bärbel Stecher
出处
期刊:The ISME Journal
[Springer Nature]
日期:2021-12-02
卷期号:16 (4): 1095-1109
被引量:180
标识
DOI:10.1038/s41396-021-01153-z
摘要
Abstract A key challenge in microbiome research is to predict the functionality of microbial communities based on community membership and (meta)-genomic data. As central microbiota functions are determined by bacterial community networks, it is important to gain insight into the principles that govern bacteria-bacteria interactions. Here, we focused on the growth and metabolic interactions of the Oligo-Mouse-Microbiota (OMM12) synthetic bacterial community, which is increasingly used as a model system in gut microbiome research. Using a bottom-up approach, we uncovered the directionality of strain-strain interactions in mono- and pairwise co-culture experiments as well as in community batch culture. Metabolic network reconstruction in combination with metabolomics analysis of bacterial culture supernatants provided insights into the metabolic potential and activity of the individual community members. Thereby, we could show that the OMM12 interaction network is shaped by both exploitative and interference competition in vitro in nutrient-rich culture media and demonstrate how community structure can be shifted by changing the nutritional environment. In particular, Enterococcus faecalis KB1 was identified as an important driver of community composition by affecting the abundance of several other consortium members in vitro. As a result, this study gives fundamental insight into key drivers and mechanistic basis of the OMM12 interaction network in vitro, which serves as a knowledge base for future mechanistic in vivo studies.
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