Biological information processing relies on the implementation of molecular switches along the cell’s signaling pathways. As a result of conformational changes, lipid or post-translational modifications, induced oligomerization, altered Ca2+ levels or changed redox conditions, the spatiotemporal patterning of molecules, macromolecular complexes or whole organelles within the living cell will be changed. Understanding this complex dynamic adaptation not only requires an intimate knowledge of a molecular switch and its mode of action, but also an understanding of the upstream and downstream biological processes that are linked to individual switching events. For example, post-translational modifications can be single- or multi-site, they can be specific or promiscuous and they can give rise to fast or slow responses. Conceptualizing the different cellular contexts that require the distinct types of molecular switches is a primary goal of our research consortium. Its realization depends on advanced technology that on the one hand allows for the acquisition of high-resolution images at the molecular and cellular level and on the other hand captures the dynamic changes in these structures. Cryo-electron microscopy and tomography will become important methodologies of TRR186 that allow for pinpointing molecular switching mechanisms in the context of large macromolecular assemblies at atomic resolution. Super-resolution light microscopy enables researchers to observe cellular architectures, for example in vesicular transport or at organellar contact sites. Correlative light and electron microscopy combines molecular and cellular imaging techniques and further pushes the limits of what can be observed in certain projects of TRR186. Dynamic aspects of cellular behavior are addressed by using stimulated emission depletion (STED), MinFlux or single molecule super-resolution microscopy, while molecular dynamics simulations and Markov State Modeling are suitable to describe the conformational landscape at the molecular level. Cellular switching behavior is conceptualized by mathematical modeling of signaling pathways, taking into account essential features, as for example the negative feed-back loops characteristic for oscillatory behavior. Ultimately, all projects will put their findings in the context of a biological process, ranging from neurotransmission, vesicle formation and secretion to receptor proximal signaling in immune cells, RNA surveillance and oscillations in virus-infected cells or in the circadian clock. Therefore, combining the knowledge about the principal building units of information processing in living systems with a cellular understanding of their prerequisites and consequences will allow us to carry the concept of molecular switches to a level from where we are better able to understand and manipulate complex cellular behavior in health and disease.

DFG Programme CRC/Transregios

International Connection Denmark

• A01 - Molecular switches in the spatio-temporal coordination of the FGF2 membrane translocation machinery (Project Heads Ewers, Helge ;  Lolicato, Fabio ;  Nickel, Walter )
• A03 - High resolution analysis of active zone cytomatrix remodeling (Project Heads Paulino, Cristina ;  Schultz, Carsten ;  Sigrist, Stephan J. ;  Walter, Alexander )
• A04 - Neurotransmitter release: spatio-temporal characterization of membrane fusion intermediates (Project Heads Rosenmund, Christian ;  Söllner, Thomas )
• A05 - The palmitoylation switch in activated T cells (Project Heads Brügger, Britta ;  Freund, Christian )
• A06 - Spatio-temporal control of CD95-activation mode (Project Heads Ewers, Helge ;  Martin-Villalba, Ana )
• A08 - Phosphoinositide-based switches in endolysosomal membrane dynamics and signaling (Project Heads Haucke, Ph.D., Volker ;  Schultz, Carsten )
• A12 - Machine-learned coarse-grained molecular dynamics of molecular complexes (Project Heads Clementi, Ph.D., Cecilia ;  Noé, Frank ;  Plattner, Nuria )
• A14 - Molecular switches regulating stress granule oscillation (Project Heads Ruggieri, Ph.D., Alessia ;  Stoecklin, Georg )
• A15 - Control of immediate early splicing through core components of the spliceosome (Project Heads Heyd, Florian ;  Wahl, Markus C. )
• A16 - Phosphoswitches controlling the timing of the circadian clock of Neurospora by modulation of long-range interactions (Project Heads Brunner, Michael ;  Herzel, Hanspeter ;  Milles, Sigrid )
• A17 - Molecular switches in the synchronization of the circadian oscillator (Project Heads Herzel, Hanspeter ;  Kramer, Achim )
• A20 - Nanoscale regulation of molecular switches at the Golgi (Project Head Bottanelli, Ph.D., Francesca )
• A21 - Switching antigens by the exchange catalyst HLA-DM (Project Heads Freund, Christian ;  Höfer, Thomas )
• A22 - Metabolic switches regulating stress tolerance in eukaryotes (Project Heads Dick, Tobias ;  Ralser, Markus )
• A23 - Control of organelle biogenesis by the Lipin switch (Project Heads Daumke, Oliver ;  Schuck, Sebastian )
• A24 - Molecular switches in the TGFβ signaling pathway (Project Heads Fiedler, Dorothea ;  Klingmüller, Ursula )
• A25 - A cargo de-ubiquitination switch in membrane remodeling in the endocytic pathway (Project Head Moser von Filseck, Joachim )
• A26 - The MEX3 protein family of RNA binding E3 ubiquitin ligases - a switch for controlling rapid mRNA decay (Project Head Absmeier, Eva Petra )
• Z02 - Quantitative image processing (Project Head Ewers, Helge )
• Z03 - Central Coordination (Project Heads Freund, Christian ;  Nickel, Walter )
• Z04 - Chemical biology and lipidomics for molecular switches (Project Heads Brügger, Britta ;  Johnsson, Kai )

• A02 - Acute control of intracellular trafficking through Rab GTPases in living tissues in Drosophila (Project Heads Boutros, Michael ;  Hiesinger, Peter Robin )
• A07 - Optical control of calcium switches that orchestrate fast signaling in the brain. (Project Heads Hegemann, Peter ;  Plested, Andrew )
• A09 - Molecular switches in polarized sorting and signaling in intestinal epithelial cells (Project Heads Boulant, Steeve ;  Haucke, Ph.D., Volker )
• A10 - Phosphoinositide switches in neurons: implications for membrane dynamics, axonal morphogenesis and the cortical actin cytoskeleton (Project Head Eickholt, Britta )
• A11 - Systematic characterization of phosphoinositide switches involved in T cell function (Project Heads Freund, Christian ;  Gavin, Anne-Claude ;  Russell, Robert B. )
• A13 - Elucidating the redox-proteolysis switch for transcriptional induction of the ubiquitin proteasome system (UPS) in space and time (Project Head Krüger, Elke Beate )
• A18 - Analysis of a SUMO switch in EGF receptor signaling (Project Heads Blüthgen, Nils ;  Melchior, Frauke )
• A19 - STARD3 as a cellular switch determining organelle contact sites (Project Head Höglinger, Doris )
• Z01 - Molecular tools for fast switching of cellular events (Project Head Schultz, Carsten )

Applicant Institution Freie Universität Berlin

Participating University Charité - Universitätsmedizin Berlin

Participating Institution Deutsches Krebsforschungszentrum (DKFZ); Max-Delbrück-Centrum für Molekulare Medizin (MDC); Max-Planck-Institut für medizinische Forschung; Leibniz-Forschungsinstitut für Molekulare Pharmakologie (FMP)
Sektion Strukturbiologie

Co-Applicant Institution Ruprecht-Karls-Universität Heidelberg

Spokespersons Professor Dr. Christian Freund, since 7/2022; Professor Dr. Walter Nickel, until 6/2022