Heterogeneous cardiac sympathetic innervation gradients promote arrhythmogenesis in murine dilated cardiomyopathy
Al-Hassan J. Dajani, Michael B. Liu, Michael A. Olaopa, Lucian Cao, Carla Valenzuela-Ripoll, Timothy J. Davis, Megan D. Poston, Elizabeth H. Smith, Jaime Contreras, Marissa Pennino, Christopher M. Waldmann, Donald B. Hoover, Jason T. Lee, Patrick Y. Jay, Ali Javaheri, Roger Slavik, Zhilin Qu, Olujimi A. Ajijola
Al-Hassan J. Dajani, Michael B. Liu, Michael A. Olaopa, Lucian Cao, Carla Valenzuela-Ripoll, Timothy J. Davis, Megan D. Poston, Elizabeth H. Smith, Jaime Contreras, Marissa Pennino, Christopher M. Waldmann, Donald B. Hoover, Jason T. Lee, Patrick Y. Jay, Ali Javaheri, Roger Slavik, Zhilin Qu, Olujimi A. Ajijola
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Research Article Cardiology

Heterogeneous cardiac sympathetic innervation gradients promote arrhythmogenesis in murine dilated cardiomyopathy

Abstract

Ventricular arrhythmias (VAs) in heart failure are enhanced by sympathoexcitation. However, radiotracer studies of catecholamine uptake in failing human hearts demonstrate a proclivity for VAs in patients with reduced cardiac sympathetic innervation. We hypothesized that this counterintuitive finding is explained by heterogeneous loss of sympathetic nerves in the failing heart. In a murine model of dilated cardiomyopathy (DCM), delayed PET imaging of sympathetic nerve density using the catecholamine analog [11C]meta-Hydroxyephedrine demonstrated global hypoinnervation in ventricular myocardium. Although reduced, sympathetic innervation in 2 distinct DCM models invariably exhibited transmural (epicardial to endocardial) gradients, with the endocardium being devoid of sympathetic nerve fibers versus controls. Further, the severity of transmural innervation gradients was correlated with VAs. Transmural innervation gradients were also identified in human left ventricular free wall samples from DCM versus controls. We investigated mechanisms underlying this relationship by in silico studies in 1D, 2D, and 3D models of failing and normal human hearts, finding that arrhythmogenesis increased as heterogeneity in sympathetic innervation worsened. Specifically, both DCM-induced myocyte electrical remodeling and spatially inhomogeneous innervation gradients synergistically worsened arrhythmogenesis. Thus, heterogeneous innervation gradients in DCM promoted arrhythmogenesis. Restoration of homogeneous sympathetic innervation in the failing heart may reduce VAs.

Authors

Al-Hassan J. Dajani, Michael B. Liu, Michael A. Olaopa, Lucian Cao, Carla Valenzuela-Ripoll, Timothy J. Davis, Megan D. Poston, Elizabeth H. Smith, Jaime Contreras, Marissa Pennino, Christopher M. Waldmann, Donald B. Hoover, Jason T. Lee, Patrick Y. Jay, Ali Javaheri, Roger Slavik, Zhilin Qu, Olujimi A. Ajijola

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Figure 3

DCM model shows a sympathetic innervation gradient and heterogeneity in innervation in the short-axis orientation.

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DCM model shows a sympathetic innervation gradient and heterogeneity in ...
(A) Schematic illustrating calculation of innervation gradients. (B) Comparisons of left ventricule (LV) internal diameter (n = 9 control, n = 9 DCM, *P = 0.0135, Shapiro-Wilk test, Welch’s t test), LV wall thickness (n = 9 control, n = 9 DCM, ***P = 0.0003, Shapiro-Wilk test, Welch’s t test), maximum epicardial to endocardial innervation gradient (n = 9 for control, n = 9 for DCM, **P = 0.0019, Shapiro-Wilk test, Mann-Whitney test), and mean apical epicardial to endocardial gradient (n = 9 control, n = 11 DCM, *P = 0.0260, Shapiro-Wilk test, Welch’s t test). (C) Immunohistochemical staining of WT (top) and DCM (bottom) heart sections. White arrows highlight innervation levels in epicardium and endocardium (1 arrow = low innervation, 3 arrows = high innervation). Scale bars are 100 μm. (D) Imaris 3D reconstruction of sympathetic innervation of heart sections from WT (top) and DCM (bottom) mice. (E) Summary heatmap of innervation gradient by level (base, mid, apex) and region (S, septal; L, lateral; A, anterior; P, posterior). (F) Short-axis innervation heterogeneity in WT and DCM mouse sections across base (n = 9 for control, n = 9 DCM, **P = 0.005, Shapiro-Wilk test, Mann-Whitney test), mid (n = 9 control, n = 9 DCM, ***P = 0.0003, Shapiro-Wilk test, Mann-Whitney test), and apex (n = 9 control, n = 9 DCM, *P = 0.0146, Shapiro-Wilk test, Mann-Whitney test) regions. (G) Reverse transcription quantitative PCR (RT-qPCR) comparing relative mRNA levels of Sema3a between WT and DCM mice in endocardial (left, n = 6 control, n = 4 DCM, **P = 0.0092, 2-way ANOVA/Tukey’s multiple comparisons test) and epicardial regions (right, n = 6 control, n = 4 DCM). Relative mRNA levels of NGF in endocardial (left, n = 6 control, n = 4 DCM) and epicardial regions (right, n = 6 control, n = 4 DCM).