SFB 944:  Physiology and Dynamics of Cellular Microcompartments

All cells are compartmentalized to facilitate and coordinate the chemical reactions that sustain the living state. Organelles as distinct compartments are themselves subdivided into various specialized functional domains, and even the cytosol contains specialized structures such as RNA granules. We refer to these structures, which are found in both bacteria and eukaryotic cells, as cellular micro-compartments to distinguish them from organelles and compartments on the one hand and quater-nary protein structures on the other hand. The crosstalk between proteins and lipids in cellular microcompartments provides a basis for suborganellar organization and is thus the foundation for a balanced and controlled physiology of healthy cells and thus organisms. To gain insights into the fundamental principles of molecular organization within these functional units, the SFB 944 aims to clarify both the physiology and spatiotemporal dynamics of selected cellular microcompartments. We thus strive for a general understanding of suborganellar organization and function, which also provides a basis for interference during diseases. Within the second funding period (2015-2018), key components, their interaction partners and their spatiotemporal organization into microcompartments have been characterized by establishing a dedicated methodological repertoire including advanced and super-resolution, as well as ultrastructural imaging techniques. The SFB 944 remains focused by and large on five central areas, namely (i) signal generation and transfer across membranes, (ii) assembly and disassembly of membrane complexes, (iii) vesicular transport and fusion, (iv) cell-cell adhesion, and (v) cytoplasmic and nuclear compartmentalization by liquid-liquid phase separation. The 16 research projects, of which five are located at the close-by University of Münster, are complemented by an integrated research training group (IRTG), a Z-project on advanced high- and super-resolution fluorescence imaging and electron microscopy, an infrastructure (INF), and a service (V) project. The recently finished research building CellNanOs (Center of Cellular Nanoanalytics Osnabrück) now provides a tailored infrastructure and further interdisciplinary links between and beyond the SFB groups.

DFG Programme Collaborative Research Centres

International Connection Switzerland

• INF - Information infrastructure project (Project Head Hensel, Michael )
• MGK - Integrated Research Training Group (Project Heads Brandt, Roland ;  Hunke, Sabine ;  Paululat, Achim ;  Steinhoff, Heinz-Jürgen )
• P01 - Function and dynamics of RNP granules during neuronal development and disease (Project Head Brandt, Roland )
• P02 - Mechanism of ferredoxin reductase membrane interaction, and its effect on photosynthetic partitioning (Project Head Hanke, Guy )
• P03 - Cell wall synthesis and cytokinesis in yeast - the role of sensors and cytokinesis regulators in the microcompartment of the bud neck (Project Head Heinisch, Jürgen J. )
• P04 - Structure and function of the dynamic adhesion/invasion microcompartment during infection of enterocytes by Salmonella (Project Head Hensel, Michael )
• P05 - Docking and recycling of secretory vesicles studied by high and super-resolution microscopy (Project Head Klingauf, Jürgen )
• P06 - Analysis of the CaaX processing machinery from yeast (Project Head Merzendorfer, Hans )
• P07 - Cardiac matrix formation in Drosophila (Project Head Paululat, Achim )
• P08 - Molecular and cellular regulation of JAK/STAT signaling (Project Head Piehler, Jacob )
• P09 - Transfer of redox-signals from chloroplast to nucleus by transient microcompartmentation of metabolic enzymes (Project Head Scheibe, Renate )
• P10 - Conformational dynamics of signal transducers in photo- und chemotaxis (Project Heads Klare, Johann P. ;  Steinhoff, Heinz-Jürgen )
• P11 - Membrane remodelling, tethering and fusion at endosome and vacuole (Project Head Ungermann, Christian )
• P12 - Regulation of V-ATPases by reversible dissociation (Project Head Wieczorek, Helmut )
• P13 - Analysis of redox effects on nuclear ROXY interactions with transcription factors (Project Head Zachgo, Sabine )
• P14 - Unraveling the mechanism and biological impact of sphingolipid homeostasis (Project Head Holthuis, Joost )
• P15 - Coordination of bacterial two component system signaling (Project Heads Hensel, Michael ;  Hunke, Sabine ;  Miskiewicz, Katarzyna )
• P16 - Role of supercomplexes in respiration and import for functional adaptation of mitochondria (Project Head Busch, Karin )
• P17 - Establishment of endosomal membrane domains by guanine nucleotide exchange factors (Project Head Kümmel, Daniel )
• P18 - The role of membrane recycling in plasma membrane organization (Project Head Wedlich-Söldner, Roland )
• P19 - Elucidating the regulation, structure, and function of interbacterial nanotubes (Project Head Kost, Christian )
• P20 - Mechanism of sphingolipid export from the endo-lysosomal system (Project Head Fröhlich, Florian )
• P21 - Functional characterization of novel mechanisms regulating SERCA activity and Ca2+ homeostasis in D. melanogaster (Project Head Harten, Heiko )
• P22 - Lipid dependence of signaling at curved membrane microcompartments (Project Head Galic, Milos )
• P24 - Architecture and function of the organelle contact sites of the vacuole (Project Head Gonzalez Montoro, Ayelen )
• P25 - Functional impact of lipid logistics on mycobacterial infection in Dictyostelium (Project Head Barisch, Caroline )
• P26 - Molecular mechanisms of pore formation by Gasdermin D in pyroptosis (Project Head Cosentino, Katia )
• P27 - ABC exporter function within their lipid microenvironment (Project Head Möller, Arne )
• V - Administration (Project Head Ungermann, Christian )
• Z - Advanced imaging techniques (Project Heads Hensel, Michael ;  Kunis, Stefan ;  Kurre, Rainer ;  Piehler, Jacob )

Applicant Institution Universität Osnabrück

Participating University Universität Münster

Spokesperson Professor Dr. Christian Ungermann