With a prevalence of between two and four percent, heart failure remains one of the most common diseases in Europe. Although tremendous progress has been made in its treatment, the morbidity and mortality of affected patients remains high. Advanced heart failure can still only be treated palliatively.We define modulatory units as cell-based and/or genetic principles that organize and control important cardiac functions, which are subject to disruption and cause cardiac dysfunction in heart failure models and humans, and therefore represent treatment targets. For example, during the second funding period, CRC 1002 contributed to the characterization and identification of molecular mechanisms that affect microdomain structures of excitation-contraction coupling processes and associated organelles, including mitochondria. We have continued to develop advanced imaging techniques for cells, tissues and organs, as well as in vivo analyses up to the in-depth characterization of patient cohorts. CRC 1002 provides an important platform for analyzing the molecular mechanisms of intracellular calcium and sodium signaling in human tissue samples as well as human stem cell and animal models. In addition, gene editing protocols were developed for cutting-edge mechanistic interrogation of human iPSC-derived cardiomyocyte and fibroblast models, as well as for studies using engineered heart muscle. A central goal of CRC 1002 is to identify new treatment targets in heart failure and to develop therapeutic strategies. The first and second funding periods have uncovered such novel targets, of which some are already at a clinical trial level. For example, we identified methylation of the RASAL1 gene as a key pathogenetic mechanism in myocardial fibrosis and from this developed a new therapeutic antifibrotic strategy. During the third funding period mechanisms underlying the transition from compensated hypertrophy to cardiac failure, in particular myocardial fibrosis, impaired calcium cycling, and altered energy metabolism will be evaluated. The unique resources available in the human biobank will provide a deeper insight into the mechanisms of myocardial reverse remodeling and clinical improvement after relief of pressure overload following aortic valve implantation performed to treat pressure overload-induced heart failure. Moreover, based on findings from the previous funding periods, we will study a new antifibrotic treatment in patients with aortic stenosis and a high degree of myocardial fibrosis.In summary, CRC 1002 will continue to improve the in-depth and mechanistic understanding of the pathophysiology of heart failure. Most importantly, we will continue to strive to close conceptual gaps and to improve treatment of heart failure patients with new therapeutic options. By monitoring the outcome of selected interventions and a thorough characterization of patient data and biosamples prior to these interventions, our studies have the potential to provide new perspectives towards a more effective, individualized treatment of heart failure.

DFG Programme Collaborative Research Centres

• A01 - cAMP and cGMP microdomains in cardiac hypertrophy and failure (Project Head Nikolaev, Viacheslav )
• A02 - Relevance of phosphatase-inhibitor-1 for SR-specific modulation of the BetaAdrenozeptor cascade (Project Head El-Armouche, Ali )
• A03 - Effects of CaMKII on arrhythmogenesis in heart failure (Project Heads Maier, Lars ;  Sossalla, Samuel )
• A04 - Functional analysis of ryanodine receptor mutations using patient-specific induced pluripotent stem cells (Project Head Guan, Kaomei )
• A05 - Molecular imaging of cardiac calcium release units (Project Heads Hell, Stefan W. ;  Lehnart, Stephan E. )
• A06 - Molecular Basis of Mitochondrial Cardiomyopathies (Project Head Rehling, Peter )
• A07 - Role of the TRC40 pathway in the proteostasis network of cardiomyocytes (Project Head Schwappach-Pignataro, Blanche )
• A08 - Translational and posttranslational control of truncated titin proteins in cardiomyocytes from dilated cardiomyopathy patients (Project Head Linke, Wolfgang )
• A09 - Local molecular nanodomain regulation of cardiac ryanodine receptor function (Project Heads Brandenburg, Sören ;  Lehnart, Stephan E. ;  Lenz, Christof )
• A10 - Peroxisomes as modulatory units in heart metabolism and heart failure (Project Head Thoms, Sven )
• A11 - Irregular ventricular activation - a novel mechanism impairing Ca2+-homeostasis and excitability in the transition to heart failure (Project Head Fischer, Thomas )
• A12 - Alternative molecular disease pathways in the presence of troponin complex mutations in cardiomyopathy (Project Head Ebert, Antje Dagmar )
• A13 - Abnormal cytosolic calcium buffering and its role in atrial arrhythmogenesis in patients with heart failure (HF) (Project Head Voigt, Wolfgang Niels )
• A14 - Gq protein activation by atrial stretch in heart failure (HF). (Project Head Brügmann, Tobias )
• C01 - Epigenetic control of cardiac fibrosis (Project Head Zeisberg, Elisabeth )
• C02 - Relevance of RhoGTPases for load-induced cardiac fibrosis (Project Head Lutz, Susanne )
• C03 - Recovery from failure: Analysis of transmural mechano-electrical dysfunction (Project Heads Hinkel, Rabea ;  Luther, Stefan )
• C04 - Fibroblast-cardiomyocyte crosstalk in health and disease: focus on mechanisms and therapeutic interventions in cardiofibroblastopathies (Project Heads Tiburcy, Malte ;  Zimmermann, Wolfram-Hubertus )
• C05 - Role of cellular immune reactions for cardiac remodeling and therapy of heart failure by stem cell transplantation (Project Head Dressel, Ralf )
• C06 - Mechanisms and regulation of coronary angiogenesis (Project Head Schäfer, Katrin )
• C07 - Cardiomyocyte Wnt/β-catenin complex activity in pathological remodeling - a tissue-specific therapeutic target (Project Head Zelarayan-Behrend, Laura C. )
• D01 - Recovery from failure – impact of fibrosis and transcription signature (Project Heads Backhaus, Sören Jan ;  Hasenfuß, Gerd )
• D02 - Novel mechanisms of genome instability in the failing heart (Project Head Wollnik, Bernd )
• D03 - Polyphosphates as causal link between inorganic phosphate and cardiac fibrosis (Project Head Zeisberg, Michael )
• D04 - Role of m6A-RNA and H3K4 methylation in heart failure (Project Heads Fischer, André ;  Toischer, Karl )
• INF - Supporting CRC 1002 research data integration, visualization and reusability (Project Heads Nußbeck, Sara ;  Zelarayan-Behrend, Laura C. )
• S01 - In vivo and in vitro disease models (Project Heads Cyganek, Lukas ;  Zimmermann, Wolfram-Hubertus )
• S02 - High-resolution fluorescence microscopy and integrative data analysis (Project Heads Hell, Stefan W. ;  Lehnart, Stephan E. )
• Z - Central organization and government (Project Head Hasenfuß, Gerd )

Applicant Institution Georg-August-Universität Göttingen

Participating Institution Deutsches Primatenzentrum GmbH (DPZ)
Leibniz-Institut für Primatenforschung; Max-Planck-Institut für biophysikalische Chemie
(Karl-Friedrich-Bonhoeffer-Institut) (aufgelöst)

Spokesperson Professor Dr. Gerd Hasenfuß