Sodium channels in the Cx43 gap junction perinexus may constitute a cardiac ephapse: an experimental and modeling study

It has long been held that electrical excitation spreads from cell-to-cell in the heart via low resistance gap junctions (GJ). However, it has also been proposed that myocytes could interact by non-GJ-mediated “ephaptic” mechanisms, facilitating propagation of action potentials in tandem with direct GJ-mediated coupling. We sought evidence that such mechanisms contribute to cardiac conduction. Using super-resolution microscopy, we demonstrate that Nav1.5 is localized within 200 nm of the GJ plaque (a region termed the perinexus). Electron microscopy revealed close apposition of adjacent cell membranes within perinexi suggesting that perinexal sodium channels could function as an ephapse, enabling ephaptic cell-to-cell transfer of electrical excitation. Acute interstitial edema (AIE) increased intermembrane distance at the perinexus and was associated with preferential transverse conduction slowing and increased spontaneous arrhythmia incidence. Inhibiting sodium channels with 0.5 μM flecainide uniformly slowed conduction, but sodium channel inhibition during AIE slowed conduction anisotropically and increased arrhythmia incidence more than AIE alone. Sodium channel inhibition during GJ uncoupling with 25 μM carbenoxolone slowed conduction anisotropically and was also highly proarrhythmic. A computational model of discretized extracellular microdomains (including ephaptic coupling) revealed that conduction trends associated with altered perinexal width, sodium channel conductance, and GJ coupling can be predicted when sodium channel density in the intercalated disk is relatively high. We provide evidence that cardiac conduction depends on a mathematically predicted ephaptic mode of coupling as well as GJ coupling. These data suggest opportunities for novel anti-arrhythmic therapies targeting noncanonical conduction pathways in the heart.

[1]  L. Leybaert,et al.  Peptides and peptide-derived molecules targeting the intracellular domains of Cx43: Gap junctions versus hemichannels , 2013, Neuropharmacology.

[2]  S. Poelzing,et al.  Heterogeneous ventricular chamber response to hypokalemia and inward rectifier potassium channel blockade underlies bifurcated T wave in guinea pig. , 2007, American journal of physiology. Heart and circulatory physiology.

[3]  G. Fishman,et al.  Subcellular heterogeneity of sodium current properties in adult cardiac ventricular myocytes. , 2011, Heart rhythm.

[4]  M. Hortsch,et al.  Structural Requirements for Interaction of Sodium Channel β1 Subunits with Ankyrin* , 2002, The Journal of Biological Chemistry.

[5]  H. van der Voort,et al.  Huygens STED Deconvolution Increases Signal-to-Noise and Image Resolution towards 22 nm , 2013, Microscopy Today.

[6]  R. Gourdie,et al.  Cx43 Associates with Nav1.5 in the Cardiomyocyte Perinexus , 2012, The Journal of Membrane Biology.

[7]  Tobias Opthof,et al.  Slow Conduction and Enhanced Anisotropy Increase the Propensity for Ventricular Tachyarrhythmias in Adult Mice With Induced Deletion of Connexin43 , 2004, Circulation.

[8]  Benjamin R. Herbert,et al.  Intercalated discs: multiple proteins perform multiple functions in non-failing and failing human hearts , 2009, Biophysical Reviews.

[9]  N. Sperelakis,et al.  Electric field interactions between closely abutting excitable cells. . , 2002, IEEE engineering in medicine and biology magazine : the quarterly magazine of the Engineering in Medicine & Biology Society.

[10]  R. Gourdie,et al.  Connexin 43 connexon to gap junction transition is regulated by zonula occludens-1 , 2011, Molecular biology of the cell.

[11]  M Delmar,et al.  Characterization of Conduction in the Ventricles of Normal and Heterozygous Cx43 Knockout Mice Using Optical Mapping , 1999, Journal of cardiovascular electrophysiology.

[12]  Yoram Rudy,et al.  Localization of Sodium Channels in Intercalated Disks Modulates Cardiac Conduction , 2002, Circulation research.

[13]  Ken-ichi Yoshida,et al.  Hemichannels in cardiomyocytes open transiently during ischemia and contribute to reperfusion injury following brief ischemia. , 2007, American journal of physiology. Heart and circulatory physiology.

[14]  James P Keener,et al.  Microdomain effects on transverse cardiac propagation. , 2014, Biophysical journal.

[15]  J. Fleischhauer,et al.  Electrical resistances of interstitial and microvascular space as determinants of the extracellular electrical field and velocity of propagation in ventricular myocardium. , 1995, Circulation.

[16]  C. Eggeling,et al.  Pathways to optical STED microscopy , 2014 .

[17]  Michael D. Schneider,et al.  Conduction Slowing and Sudden Arrhythmic Death in Mice With Cardiac-Restricted Inactivation of Connexin43 , 2001, Circulation research.

[18]  J E Saffitz,et al.  Distribution and Three‐Dimensional Structure of Intercellular Junctions in Canine Myocardium , 1989, Circulation research.

[19]  Y Rudy,et al.  Ionic mechanisms of propagation in cardiac tissue. Roles of the sodium and L-type calcium currents during reduced excitability and decreased gap junction coupling. , 1997, Circulation research.

[20]  J. Martens,et al.  Ordered Assembly of the Adhesive and Electrochemical Connections within Newly Formed Intercalated Disks in Primary Cultures of Adult Rat Cardiomyocytes , 2010, Journal of biomedicine & biotechnology.

[21]  R. Young,et al.  Myocytes, Myometrium, and Uterine Contractions , 2007, Annals of the New York Academy of Sciences.

[22]  S. Poelzing,et al.  Mechanisms underlying increased right ventricular conduction sensitivity to flecainide challenge. , 2008, Cardiovascular research.

[23]  W. Birchmeier,et al.  Sodium current deficit and arrhythmogenesis in a murine model of plakophilin-2 haploinsufficiency. , 2012, Cardiovascular research.

[24]  James P. Keener,et al.  Ephaptic Coupling in Cardiac Myocytes , 2013, IEEE Transactions on Biomedical Engineering.

[25]  C. Green,et al.  Gap junction connexon configuration in rapidly frozen myocardium and isolated intercalated disks , 1984, The Journal of cell biology.

[26]  C. Green,et al.  Validation of immunohistochemical quantification in confocal scanning laser microscopy: a comparative assessment of gap junction size with confocal and ultrastructural techniques. , 1993, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[27]  Nicholas Sperelakis Combined electric field and gap junctions on propagation of action potentials in cardiac muscle and smooth muscle in PSpice simulation. , 2003, Journal of electrocardiology.

[28]  D. Rosenbaum,et al.  Unique Properties of Cardiac Action Potentials Recorded with Voltage‐Sensitive Dyes , 1996, Journal of cardiovascular electrophysiology.

[29]  David Fenyö,et al.  Super-resolution imaging reveals that loss of the C-terminus of connexin43 limits microtubule plus-end capture and NaV1.5 localization at the intercalated disc. , 2014, Cardiovascular research.

[30]  A. Kleber,et al.  Slow conduction in cardiac tissue, I: effects of a reduction of excitability versus a reduction of electrical coupling on microconduction. , 1998, Circulation research.

[31]  Stefan Luther,et al.  SAP97 and Dystrophin Macromolecular Complexes Determine Two Pools of Cardiac Sodium Channels Nav1.5 in Cardiomyocytes , 2011, Circulation research.

[32]  J E Saffitz,et al.  High resolution optical mapping reveals conduction slowing in connexin43 deficient mice. , 2001, Cardiovascular research.

[33]  J. D. de Bakker,et al.  Reduced heterogeneous expression of Cx43 results in decreased Nav1.5 expression and reduced sodium current that accounts for arrhythmia vulnerability in conditional Cx43 knockout mice. , 2012, Heart rhythm.

[34]  K. Schalper,et al.  Cell membrane permeabilization via connexin hemichannels in living and dying cells. , 2010, Experimental cell research.

[35]  Y. Rudy,et al.  Basic mechanisms of cardiac impulse propagation and associated arrhythmias. , 2004, Physiological reviews.

[36]  N. Sperelakis,et al.  An electric field mechanism for transmission of excitation between myocardial cells. , 2002, Circulation research.

[37]  R. Price,et al.  Increased Association of ZO-1 With Connexin43 During Remodeling of Cardiac Gap Junctions , 2002, Circulation research.

[38]  Christof Koch,et al.  Ephaptic coupling of cortical neurons , 2011, Nature Neuroscience.

[39]  Rengasayee Veeraraghavan,et al.  Interstitial volume modulates the conduction velocity-gap junction relationship. , 2012, American journal of physiology. Heart and circulatory physiology.

[40]  J. Tavernier,et al.  Selective inhibition of Cx43 hemichannels by Gap19 and its impact on myocardial ischemia/reperfusion injury , 2012, Basic Research in Cardiology.

[41]  James P Keener,et al.  Modeling electrical activity of myocardial cells incorporating the effects of ephaptic coupling , 2010, Proceedings of the National Academy of Sciences.

[42]  Jacques M T de Bakker,et al.  Combined reduction of intercellular coupling and membrane excitability differentially affects transverse and longitudinal cardiac conduction. , 2009, Cardiovascular research.

[43]  Yoram Rudy,et al.  Impulse Propagation in Synthetic Strands of Neonatal Cardiac Myocytes With Genetically Reduced Levels of Connexin43 , 2003, Circulation research.

[44]  Yoichiro Mori,et al.  Ephaptic conduction in a cardiac strand model with 3D electrodiffusion , 2008, Proceedings of the National Academy of Sciences.

[45]  M. Kamermans,et al.  Ephaptic communication in the vertebrate retina , 2013, Front. Hum. Neurosci..