The Max Planck Institute Magdeburg invites you to its series of colloquia. Top-class scientists, invited by the Max Planck Institute Magdeburg, give a survey of their research work. Everybody who is interested, is invited to attend.
Microbiomes represent highly dynamic and heterogeneous systems, which exhibit tremendous complexity at all levels. High-throughput molecular measurements are allowing unprecedented insights into microbiome composition, physiology, ecology and evolution in situ. Our group has pioneered a comprehensive toolbox comprising wet- and dry-lab methodologies to enable systematic measurements of microbiomes over space and time, the integration and analysis of the resulting multi-omic data, and experimental models for rapidly testing hypotheses in vitro. The application of these methods has culminated in essential new insights regarding niche ecology and resulting lifestyle strategies of specific microbial populations in situ as well as the discovery of keystone functional genes. In the context of the human gut microbiome, it has highlighted the disruption of ecosystem services in the context of human disease (type 1 diabetes). To study the ramifications of such perturbations, a microfluidics-based model of the gastrointestinal human-microbe interface has been developed called HuMiX. HuMiX allows the probing of the molecular interactions between human and microbial cell contingents and has highlighted the importance of microbial metabolism in governing human cell physiology in the gut. The developed toolbox is also particularly pertinent for the exploration of the vast expanse of unknown features in microbiomes, ranging from uncharacterised organisms to proteins of unknown function and small molecules. Thereby, Microbial Systems Ecology offers great potential for the discovery of new biological functions in the future.