Stress-related mental disorders such as anxiety, depression, chronic pain, and addiction cause enormous personal suffering and large economic and societal costs. Progress in our understanding of disease mechanisms and, in particular, in the development of new therapies in the last decades has been limited, despite intense research. The incidence of stress-related mental disorders remains high. In CRC 1193, we therefore complement pathophysiological research with an alternative strategy, which is to investigate protective mechanisms that support the maintenance of mental health during and after adversity (e.g., potentially traumatizing events, challenging life circumstances or transitions, physical illness). Focusing on resilience rather than on pathophysiology represents a paradigm shift in mental health research and has great potential for the development of new prevention strategies. In CRC 1193, we aim at advancing this paradigm shift by (i) developing a coherent theoretical framework for the neurobiological study of resilience to stress-related mental dysfunction (Goal 1), (ii) identifying and understanding neurobiological resilience mechanisms (Goal 2), and (iii) exploiting the obtained insights for the development of new or improved prevention strategies (Goal 3). Goal 1 (theory development) starts with the assumption that flexible short- and long-term regulation of stress responses is key in minimizing resource depletion and allostatic costs caused by stress. On this basis, researchers in the CRC initiative pursue two theoretical approaches, the first one of which is centered on the regulation of neural excitability and neural-network activity during and after stress, and the second one on the neurobiological underpinnings of stress-regulatory appraisal (emotional evaluation) processes. Over the course of the CRC, both frameworks will be evaluated and refined with the ultimate goal to consolidate the results into a unified theory of neurobiological resilience mechanisms. Goal 1 and Goal 2 (empirical investigation of neurobiological resilience mechanisms) require an interdisciplinary and integrative research strategy combining molecular-cellular and neural network-based with behavioral and cognitive analyses. To this end, all subprojects are designed to include at least two of these levels of analysis. The projects are focused on fine-grained mechanistic studies in animal and human models, and the results obtained will be incorporated into theory development. Wherever possible, the projects perform causal manipulations of the neural mechanisms that they investigate, in order to gain new ideas for the development of preventive interventions.

DFG Programme Collaborative Research Centres

• A01 - Active resilience mechanisms of dopamine midbrain neurons (Project Heads Roeper, Jochen ;  Schweiger, Susann )
• A02 - Unraveling the relation between adult-born hippocampal neurons’ circuit activity and resilience (Project Heads Berninger, Benedikt ;  Leschik, Julia )
• A03 - Dissecting molecular pathways to resilience: the role of DRR1 (Project Heads Acker-Palmer, Amparo ;  Müller, Marianne )
• A04 - Developing a zebrafish model to identify novel mediators of resilience mechanisms (Project Heads Ryu, Ph.D., Soojin ;  Schuman, Erin M. )
• A05 - Deciphering the epigenetic basis of resilience (Project Heads Schweiger, Susann ;  Winter, Ph.D., Jennifer )
• B01 - Finding the good in the bad: fear extinction reconceptualized as an appetitive learning process (Project Heads Duvarci, Sevil ;  Kalisch, Raffael )
• B02 - Cortical mechanisms of adaptive fear extinction underlying stress resilience (Project Head Letzkus, Ph.D., Johannes )
• B03 - Fear network interactions underlying resilience to stress (Project Head Sigurdsson, Torfi )
• B04 - Lipid signaling by anandamide and the bliss of resilience: genetic models at cellular and neural-network levels (Project Heads Luhmann, Heiko J. ;  Lutz, Beat )
• B05 - Regulation of neural excitability and neural-network function in resilience - a multimodal and (back-) translational approach (Project Heads Groppa, Sergiu ;  Nitsch, Robert ;  Stroh, Albrecht ;  Vogt, Johannes )
• C01 - Making extinction last: mechanistically understanding and causally probing the role of the ventromedial prefrontal cortex in extinction memory consolidation (Project Heads Bergmann, Til Ole ;  Kalisch, Raffael ;  Stroh, Albrecht )
• C02 - The functional contributions of prefrontal dopamine and norepinephrine projections to cognitive and social resilience (Project Head Duvarci, Sevil )
• C03 - Psychological Flexibility as Active Resilience Mechanism: Neurocognitive Mechanisms and Dopaminergic Mediation (Project Heads Fiebach, Christian ;  Schreckenberger, Mathias )
• C04 - Goal pursuit despite emotional distraction: Neural-network mechanisms of emotional interference inhibition and their role for resilience (Project Heads Müller-Dahlhaus, Florian ;  Tüscher, Oliver ;  Wibral, Michael )
• C05 - Cognitive emotion regulation in the face of stress (Project Head Wessa, Michèle )
• C06 - The automatic and strategic adaptation of affective processing biases: Effects of context and control (Project Head Basten-Wissel, Ulrike )
• C07 - Neuropsychological and neurochemical underpinnings of perceived controllability: a translational approach (Project Heads Slattery, Ph.D., David ;  Wessa, Michèle )
• Z01 - Central coordination (Project Head Lutz, Beat )
• Z02 - Development and refinement of mouse models for studying stress resilience (Project Heads Lutz, Beat ;  Müller, Marianne )
• Z03 - Longitudinal determination of resilience in humans to identify mechanisms of resilience to modern-life stressors (Project Heads Lieb, Klaus ;  Reif, Andreas )

Applicant Institution Johannes Gutenberg-Universität Mainz

Participating University Albert-Ludwigs-Universität Freiburg; Georg-August-Universität Göttingen; Goethe-Universität Frankfurt am Main

Participating Institution Leibniz-Institut für Resilienzforschung (LIR); Max-Planck-Institut für Hirnforschung

Spokesperson Professor Dr. Beat Lutz