Heart failure is a rapidly growing health problem, leading to death from arrhythmias or pump failure. Alterations in myocyte neurohumoral regulation, ion currents, calcium (Ca2+) handling, and contractility, accompanied by ventricular hypertrophy and structural remodeling all contribute to heart failure. Understanding the interactions of these complex biochemical and biophysical functions requires quantitative systems models that also integrate over multiple physical scales. Well-characterized and readily perturbed experimental systems are needed to validate computational models. There are now many gene-targeted mouse models that recapitulate major pathophysiological and clinical features of heart failure. The wealth of multi-scale data on alterations in signaling, electrophysiology, Ca2+ handling, myofilament function and tissue structure that can be measured in mice cannot be obtained in humans, but the new models proposed here will provide a systematic framework to extrapolate findings to the clinical setting. Ca2+-calmodulin dependent protein kinase (CaMKII) is upregulated and more active in heart failure, and is a key regulator of cellular subsystems contributing to acute mechanical and electrical dysfunction as well as chronic cardiac remodeling in heart failure. CaMKII overexpression leads to heart failure in mice, while CaMKII knockout or inhibition can protect against failure. While other pathways are also important, we focus here on mouse models in which multiple key heart failure phenotypes are all affected by null- or over-expression of CaMKII. We will take advantage of ongoing studies in our labs to extend the rich set of experimental data required for model formulation and validation. The investigators propose a closely integrated combination of novel experimental and computational studies that take advantage of strong interdisciplinary synergy between the PIs (Bers at UCD &McCulloch at UCSD) and collaborating faculty at Davis (Colleen Clancy and Leighton Izu), San Diego (Joan Heller Brown and Jeffrey Omens) and the University of Virginia (Jeffrey Saucerman).
The aims test our overall hypothesis that Ca2+-CaMKII signaling controls multiple multi-scale processes that synergize in maladaptive electrophysiological, Ca2+ handling, contractile and hypertrophic remodeling leading to heart failure, including: (1) crosstalk between 2-adrenergic receptor and CaMKII signaling;(2) triggered arrhythmia susceptibility at the subcellular, cellular, tissue and organ scales;(3) cardiac mechanical dysfunction at cell, tissue and organ scales;and (4) hypertrophic transcription and maladaptive remodeling in response to stress.
Each aim i ncludes the formulation and sensitivity analysis of new models, validation studies making use of genetically engineered mice, and testing of specific hypotheses. Models and data will be distributed freely and widely making use of software and database infrastructure supported by the National Biomedical Computation Resource at UCSD, via the CellML repository, and through new releases of LabHeart software tool developed by the UC Davis group.

Public Health Relevance

Heart failure is a growing public health problem that affects over 5 million Americans and has poor five-year survival. It is a complex syndrome that affects the hormonal, electrical and mechanical functions of the heart. This proposal uses the tools of systems biology, especially computer models and genetically engineered model organisms, to synthesize information on the diverse alterations in the failing heart into an integrated computer model for better understanding and treatment heart failure.

National Institute of Health (NIH)
National Heart, Lung, and Blood Institute (NHLBI)
Research Project (R01)
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Special Emphasis Panel (ZRG1-VH-D (50))
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Larkin, Jennie E
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University of California San Diego
Engineering (All Types)
Schools of Arts and Sciences
La Jolla
United States
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Cranford, Jonathan P; O'Hara, Thomas J; Villongco, Christopher T et al. (2018) Efficient Computational Modeling of Human Ventricular Activation and Its Electrocardiographic Representation: A Sensitivity Study. Cardiovasc Eng Technol 9:447-467
Lye, Theresa H; Vincent, Kevin P; McCulloch, Andrew D et al. (2018) Tissue-Specific Optical Mapping Models of Swine Atria Informed by Optical Coherence Tomography. Biophys J 114:1477-1489
Hegyi, Bence; Bossuyt, Julie; Griffiths, Leigh G et al. (2018) Complex electrophysiological remodeling in postinfarction ischemic heart failure. Proc Natl Acad Sci U S A 115:E3036-E3044
Willeford, Andrew; Suetomi, Takeshi; Nickle, Audrey et al. (2018) CaMKII?-mediated inflammatory gene expression and inflammasome activation in cardiomyocytes initiate inflammation and induce fibrosis. JCI Insight 3:
Frank, Deborah U; Sutcliffe, Matthew D; Saucerman, Jeffrey J (2018) Network-based predictions of in vivo cardiac hypertrophy. J Mol Cell Cardiol 121:180-189
Sutcliffe, Matthew D; Tan, Philip M; Fernandez-Perez, Antonio et al. (2018) High content analysis identifies unique morphological features of reprogrammed cardiomyocytes. Sci Rep 8:1258
Lewalle, Alexandre; Land, Sander; Carruth, Eric et al. (2018) Decreasing Compensatory Ability of Concentric Ventricular Hypertrophy in Aortic-Banded Rat Hearts. Front Physiol 9:37
Yan, Jiajie; Zhao, Weiwei; Thomson, Justin K et al. (2018) Stress Signaling JNK2 Crosstalk With CaMKII Underlies Enhanced Atrial Arrhythmogenesis. Circ Res 122:821-835
Kennedy, Matthew; Bers, Donald M; Chiamvimonvat, Nipavan et al. (2017) Dynamical effects of calcium-sensitive potassium currents on voltage and calcium alternans. J Physiol 595:2285-2297
Gray, Charles B B; Suetomi, Takeshi; Xiang, Sunny et al. (2017) CaMKII? subtypes differentially regulate infarct formation following ex vivo myocardial ischemia/reperfusion through NF-?B and TNF-?. J Mol Cell Cardiol 103:48-55

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