Microbial life has a huge impact on human society determining our health, nutrition and the functioning of whole ecosystems. In nature, microorganisms do not live as autarkic units but interact and communicate with each other resulting in the exchange of nutrients and information, an active process we call “networking”. This microbial networking is operational at different scales ranging from intracellular endosymbionts to intercellular cross-kingdom communities. A highly evolved example of networking is displayed by organelles such as mitochondria and chloroplasts, where endosymbiotic bacterial cells gave up their individuality to become integral, but still semi-autonomous, parts of their eukaryotic hosts. At the community level, higher-order biological entities are formed that consist of prokaryotic and eukaryotic members and are commonly referred to as microbiomes. CRC MibiNet’s vision is to understand microbial networking in its full complexity to explain how organelles evolve and how microbiome functions emerge. Therefore, we address the establishment, maintenance and evolution of microbial networking from intracellular interactions of organelles or endosymbionts and their host cell (A projects) to intercellular interactions in cross-kingdom communities (B projects) using state-of-the-art in vivo approaches and metabolomics (Z projects). We propose that the physiological and metabolic state of each member determines the dynamic and spatial organisation of microbial networking. To address this hypothesis, we will uncover central hubs of the underlying networks to identify which metabolic, regulatory and physical interactions are predominant at different networking scales. At the metabolic level, we will initially focus on the essential micronutrient iron as well as the macronutrient carbon and its link to energy metabolism. We will follow a new approach using minimal invasive switches of gene functions to alter microbial interactions followed by in vivo monitoring of resulting metabolic changes and evaluation by computational methods to gain predictable designs of underlying concepts. CRC MibiNet will pursue a profound “learning from nature” strategy: fundamental principles and unifying concepts from natural examples of stable microbial interactions will be challenged by implementing them in the synthetic construction of designer organelles, endosymbionts and cross-kingdom communities. With the interdisciplinary training programme MibiNeⓍt, this CRC puts a special emphasis on the education of the next generation of microbiologists with important skills in data science and modelling enabling them to act at the interface between disciplines. Ultimately, the coordinated effort of CRC MibiNet will open up new horizons for the engineering of microbial networking for future medical, agricultural and biotechnological applications.

DFG Programme Collaborative Research Centres

• A01 - Integration of a bacterial endosymbiont into the intracellular networks of a eukaryotic host cell (Project Heads Nowack, Eva C.M. ;  Zurbriggen, Matias Daniel )
• A02 - Dependency of mitochondrial energy metabolism on inositol-pyrophosphate-driven microtubule logistics (Project Head Fleig, Ursula-Nicole )
• A03 - Coupling of mitochondrial energy metabolism with microtubule-dependent mRNA logistics (Project Heads Feldbrügge, Michael ;  Zurbriggen, Matias Daniel )
• A04 - Links between mitochondrial energy metabolism and intracellular stress response pathways (Project Heads Reichert, Andreas ;  Schmitt, Lutz )
• A05 - Itaconic acid and its derivatives: from mitochondrial functions to intercellular communication (Project Heads Blank, Ph.D., Lars ;  Wierckx, Nick )
• A07 - In vitro evolution of a synthetic organelle inside a picolitre habitat (Project Heads Eisenhut, Marion ;  Kohlheyer, Dietrich ;  Weber, Andreas P.M. )
• A08 - Race for carbon during the switch of plant pathogenic bacteria from planktonic growth to colonisation (Project Head Frommer, Wolf-Bernd )
• A09 - Role of ferritin-like proteins in the microbial iron metabolic network (Project Heads Bott, Michael ;  Monzel, Cornelia )
• B01 - Race for iron: impact of siderophore- and heme-mediated networking on spatial interactions in defined microbial communities (Project Heads Drepper, Thomas ;  Frunzke, Julia ;  Kohlheyer, Dietrich )
• B02 - Role of carbohydrate-binding proteins and antimicrobial proteins (AMPs) in natural lichen and synthetic cross-kingdom communities (Project Heads Altegoer, Florian ;  Pauly, Markus ;  Thomma, Bart ;  Usadel, Björn )
• B03 - Race for carbon: molecular carbon economics and logistics within a synthetic microbial community (Project Heads Axmann, Ilka Maria ;  Matuszynska, Anna ;  Schipper, Kerstin )
• B04 - Designing synthetic phototrophic microbial ecosystems (Project Heads Ebenhöh, Oliver ;  Garrido-Oter, Ruben ;  Thomma, Bart )
• Z01 - Sensors for monitoring microbial metabolism and its regulation: structural and imaging approaches (Project Heads Frommer, Wolf-Bernd ;  Smits, Sander ;  Weidtkamp-Peters, Stefanie )
• Z02 - Metabolic and isotopologue profiling of intra- and intercellular metabolic networks (Project Head Westhoff, Philipp )
• Z03 - INF: data management and central database for CRC MibiNet (Project Head Usadel, Björn )
• Z04 - MibiNeⓍt: integrated Research Training Group (iRTG) (Project Heads Axmann, Ilka Maria ;  Frunzke, Julia )
• Z05 - Central coordination of CRC MibiNet (Project Head Feldbrügge, Michael )

Applicant Institution Heinrich-Heine-Universität Düsseldorf

Participating Institution Forschungszentrum Jülich; Max-Planck-Institut für Pflanzenzüchtungsforschung

Participating University Rheinisch-Westfälische Technische Hochschule Aachen; Universität Bielefeld; Universität zu Köln

Spokesperson Professor Dr. Michael Feldbrügge