In most organs, tissue damage is a reversible process that is followed by an efficient regenerative response that re-establishes tissue structure and function. In the mammalian central nervous system (CNS), however, injuries often result in persistent lesions that permanently alter tissue function and sometimes even result in progressive neurological deficits. Despite the CNS’ poor tolerance to damage and its low regenerative capacity, the response to acute CNS injury can be variable and ranges from irreversible damage to almost complete recovery. The underlying reasons for these different outcomes are unknown. A central obstacle for progress in this area has been the complex biology underlying the response to CNS injury which, irrespective of its trigger, is followed by a multicellular response that encompasses different cell types (including neurons, astrocytes, microglia, oligodendrocytes, and their precursors, as well as infiltrating immune cells). Therefore, the major aim of this CRC is to understand the biology of the multicellular response that determines recovery after CNS injury and to identify the checkpoints that govern the balance between perpetuation of tissue damage and restitution of function. We explore the unique patterns of damage and reconstitution resulting from various acute insults to the CNS caused by inflammation, trauma, metabolic dysfunction, or ischemia and seek to unravel the underlying mechanisms that dictate whether the tissue undergoes a regenerative or scarring response. Our CRC consists of immunologists, neurobiologists, and glial biologists, specialized in intra-vital, cell-biological, and molecular analyses of acute CNS damage. These complementary expertises and approaches allow us to reveal and modulate cellular interactions and their structural and functional consequences as well as their underlying molecular signals and pathways. Our goal is to define the immunological, glial, and neuronal checkpoints that determine the outcome of CNS injuries, and to develop intervention strategies targeting those checkpoints that guide an injured CNS tissue towards reconstitution. In the first funding period our focus has been on the analysis of distinct damage models and the cellular responses, subcellular alterations, and molecular signals that determine recovery. In the second funding period we want to build on these insights and emphasize approaches that allow i) dissecting the cellular networks and interactions that interconnect immune, glial and neuronal responses after injury, ii) integrating findings across distinct injury models to reveal shared and disease-specific principles of the recovery process and iii) validating experimental findings in human tissue samples and humanized model systems. Together, these studies will lay the foundation for the design of novel treatment strategies that harness the endogenous repair potential of the CNS to promote tissue restitution and limit scarring.

DFG Programme CRC/Transregios

• A01 - CD96 as checkpoint for the persistence of T cell responses in the central nervous system (Project Head Korn, Thomas )
• A02 - Multicellular interactions of microglia in the chronically inflamed brain after ischemic stroke (Project Head Liesz, Arthur )
• A03 - Checkpoints determining recovery from acute autoimmune CNS grey matter lesions (Project Head Flügel, Alexander )
• A04 - The role of the meninges in the resolution of acute autoimmune CNS lesions (Project Heads Merlini, Arianna ;  Odoardi, Francesca )
• A06 - Linking lipid metabolism to inflammation in models of demyelinating injury (Project Heads Berghoff, Stefan ;  Cantuti-Castelvetri, Ph.D., Ludovico ;  Simons, Mikael Jakob )
• A08 - Deciphering the heterogeneity of B-lymphoid subpopulations impacting on CNS recovery from acute multiple sclerosis bouts (Project Heads Weber, Martin ;  Wienands, Jürgen )
• B01 - Function of satellite oligodendrocytes in remyelination (Project Heads Simons, Mikael Jakob ;  Stadelmann-Nessler, Christine )
• B02 - Targeting immunological networks to promote recovery in childhood-onset white matter diseases (Project Heads Brück, Wolfgang ;  Gärtner, Jutta ;  Nessler, Stefan )
• B03 - Glia-glia interactions as checkpoints of antibody-mediated CNS lesion formation and resolution (Project Heads Herwerth, Marina ;  Misgeld, Thomas ;  Stadelmann-Nessler, Christine )
• B05 - Cross-talk between innate immunity and extracellular vesicles (EV) forms a checkpoint regulating long-lasting neuroinflammation after brain injury (Project Head Ninkovic, Jovica )
• B06 - Unmasking molecular networks that orchestrate human glial cell responses during CNS injury (Project Head Schäfer, Simon T. )
• B07 - Molecular checkpoints regulating the repair capacity of surviving oligodendrocytes in an inflammatory environment (Project Heads Jaekel, Sarah ;  Kerschensteiner, Martin )
• C01 - EPO/EPOR signalling in the recovery from brain injury and disease (Project Heads Ehrenreich, Hannelore Maria ;  Nave, Ph.D., Klaus-Armin )
• C02 - In vivo detection and targeting of neuroenergetic checkpoints determining neuronal resilience and function during CNS inflammation (Project Heads Kerschensteiner, Martin ;  Misgeld, Thomas )
• C03 - Cellular and molecular checkpoints of circuit refinement following traumatic injuries of the CNS (Project Head Bareyre, Florence )
• C04 - Brain network remodelling as a checkpoint of recovery after acute retinal injury (Project Heads Godinho, Leanne ;  Portugues, Ruben )
• C05 - Glial checkpoints for neuronal circuitry recovery (Project Heads Götz, Magdalena ;  Kerschensteiner, Martin )
• C06 - Understanding checkpoints of interneuron sculpting for neuronal remodelling of microcircuits to promote CNS repair (Project Head Wahl, Ph.D., Anna-Sophia )
• V01 - Central Tasks (Project Heads Flügel, Alexander ;  Simons, Mikael Jakob )
• Z01 - Bioimaging and Tissue Analysis Platform (Project Heads Jakobs, Stefan ;  Kerschensteiner, Martin ;  Misgeld, Thomas ;  Schifferer, Martina ;  Stadelmann-Nessler, Christine )
• Z02 - Genomics and Bioinformatics Platform (Project Heads Beißbarth, Tim ;  Gokce, Ozgun ;  Götz, Magdalena ;  Klughammer, Ph.D., Johanna ;  Simons, Mikael Jakob )

• A07 - Functional proteomics dissection of phagocyte derived signals during CNS inflammation and recovery (Project Head Meissner, Felix )
• B04 - Interaction of glial and CNS infiltrating immune cells in the recovery from acute inflammatory and hypoxic tissue damage in the CNS (Project Head Rothhammer, Veit )

Applicant Institution Georg-August-Universität Göttingen, since 1/2024

Participating Institution Helmholtz Zentrum München
Deutsches Forschungszentrum für Gesundheit und Umwelt; Max-Planck-Institut für Multidisziplinäre Naturwissenschaften; Deutsches Zentrum für Neurodegenerative Erkrankungen (DZNE)
Standort München

Co-Applicant Institution Ludwig-Maximilians-Universität München; Technische Universität München (TUM)

Spokespersons Professor Dr. Alexander Flügel, since 1/2024; Professor Dr. Mikael Jakob Simons, until 12/2023