Role of gap junctions in the propagation of the cardiac action potential.

Gap junctions play a pivotal role for the velocity and the safety of impulse propagation in cardiac tissue. Under physiologic conditions, the specific subcellular distribution of gap junctions together with the tight packaging of the rod-shaped cardiomyocytes underlies anisotropic conduction, which is continuous at the macroscopic scale. However, when breaking down the three-dimensional network of cells into linear single cell chains, gap junctions can be shown to limit axial current flow and to induce 'saltatory' conduction at unchanged overall conduction velocities. In two- and three-dimensional tissue, these discontinuities disappear due to lateral averaging of depolarizing current flow at the activation wavefront. During gap junctional uncoupling, discontinuities reappear and are accompanied by slowed and meandering conduction. Critical gap junctional uncoupling reduces conduction velocities to a much larger extent than does a reduction of excitability, which suggests that the safety for conduction is higher at any given conduction velocity for gap junctional uncoupling. In uniformly structured tissue, gap junctional uncoupling is accompanied by a parallel decrease in conduction velocity. However, this is not necessarily the case for non-uniform structures like tissue expansion where partial uncoupling paradoxically increases conduction velocity and has the capacity to remove unidirectional conduction blocks. Whereas the impact of gap junctions on impulse conduction is generally assessed from the point of view of cell coupling among cardiomyocytes, it is possible that other cell types within the myocardium might be coupled to cardiomyocytes as well. In this context, it has been shown that fibroblasts establish successful conduction between sheets of cardiomyocytes over distances as long as 300 microm. This might not only explain electrical synchronization of heart transplants but might be of importance for cardiac diseases involving fibrosis. Finally, the intriguing fact that sodium channels are clustered at the intercalated disc recently rekindled the provocative question of whether gap junctions alone are responsible for impulse propagation or whether electric field mechanisms might account for conduction as well. Whereas computer simulations show the feasibility of conduction in the absence of gap junctional coupling, a definite answer to this question must await further investigations into the biophysical properties of the intercalated disc.

[1]  K. Willecke,et al.  Biophysical properties of gap junction channels formed by mouse connexin40 in induced pairs of transfected human HeLa cells. , 1995, Biophysical journal.

[2]  S. Weidmann,et al.  The electrical constants of Purkinje fibres , 1952, The Journal of physiology.

[3]  I. Hisatome,et al.  Effects of catecholamines on the residual sodium channel dependent slow conduction in guinea pig ventricular muscles under normoxia and hypoxia. , 1995, Cardiovascular research.

[4]  J. E. Mann,et al.  Evaluation of electric field changes in the cleft between excitable cells. , 1977, Journal of theoretical biology.

[5]  R. Veenstra,et al.  Regulation of Connexin43 Gap Junctional Conductance by Ventricular Action Potentials , 2003, Circulation research.

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

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

[8]  I. LeGrice,et al.  Fibroblast Network in Rabbit Sinoatrial Node: Structural and Functional Identification of Homogeneous and Heterogeneous Cell Coupling , 2004, Circulation research.

[9]  Alex McFadden,et al.  Organization of fibroblasts in the heart , 2004, Developmental dynamics : an official publication of the American Association of Anatomists.

[10]  R C Barr,et al.  Electrophysiological effects of remodeling cardiac gap junctions and cell size: experimental and model studies of normal cardiac growth. , 2000, Circulation research.

[11]  José Jalife,et al.  Null Mutation of Connexin 43 Causes Slow Propagation of Ventricular Activation in the Late Stages of Mouse Embryonic Development , 2001 .

[12]  S. Marom,et al.  Electrophysiological Modulation of Cardiomyocytic Tissue by Transfected Fibroblasts Expressing Potassium Channels: A Novel Strategy to Manipulate Excitability , 2002, Circulation.

[13]  Nicholas S. Peters,et al.  Remodeling of Gap Junctional Channel Function in Epicardial Border Zone of Healing Canine Infarcts , 2003, Circulation research.

[14]  IchiroManabe,et al.  Gene Expression in Fibroblasts and Fibrosis , 2002 .

[15]  S A Cohen,et al.  Immunocytochemical localization of rH1 sodium channel in adult rat heart atria and ventricle. Presence in terminal intercalated disks. , 1996, Circulation.

[16]  S. Weidmann Electrical constants of trabecular muscle from mammalian heart , 1970, The Journal of physiology.

[17]  S. Grinstein,et al.  Subcellular localization of the Na+/H+ exchanger NHE1 in rat myocardium. , 1999, The American journal of physiology.

[18]  J E Saffitz,et al.  Tissue-specific determinants of anisotropic conduction velocity in canine atrial and ventricular myocardium. , 1994, Circulation research.

[19]  W. Catterall,et al.  An unexpected role for brain-type sodium channels in coupling of cell surface depolarization to contraction in the heart , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[20]  F A Roberge,et al.  Directional characteristics of action potential propagation in cardiac muscle. A model study. , 1991, Circulation research.

[21]  Y. Rudy,et al.  Propagation Delays Across Cardiac Gap Junctions and their Reflection in Extracellular Potentials: A Simulation Study , 1991 .

[22]  R. W. Joyner,et al.  Unidirectional block between Purkinje and ventricular layers of papillary muscles. , 1984, The American journal of physiology.

[23]  P. Ursell,et al.  Structural and Electrophysiological Changes in the Epicardial Border Zone of Canine Myocardial Infarcts during Infarct Healing , 1985, Circulation research.

[24]  Capelle,et al.  Slow conduction in the infarcted human heart. 'Zigzag' course of activation. , 1993, Circulation.

[25]  Jan P. Kucera,et al.  Photolithographically defined deposition of attachment factors as a versatile method for patterning the growth of different cell types in culture , 2003, Pflügers Archiv.

[26]  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.

[27]  M. Spach,et al.  Relating Extracellular Potentials and Their Derivatives to Anisotropic Propagation at a Microscopic Level in Human Cardiac Muscle: Evidence for Electrical Uncoupling of Side‐to‐Side Fiber Connections with Increasing Age , 1986, Circulation research.

[28]  S. Rohr,et al.  Optical recording system based on a fiber optic image conduit: assessment of microscopic activation patterns in cardiac tissue. , 1998, Biophysical journal.

[29]  W. J. Mueller,et al.  Propagation of Impulses across the Purkinje Fiber‐Muscle Junctions in the Dog Heart , 1970, Circulation research.

[30]  A. Wilde,et al.  Changes in conduction velocity during acute ischemia in ventricular myocardium of the isolated porcine heart. , 1986, Circulation.

[31]  L. Girardier,et al.  Homo- and heterocellular junctions in cell cultures: an electrophysiological and morphological study. , 1969, Progress in Brain Research.

[32]  Y Rudy,et al.  Electrophysiologic effects of acute myocardial ischemia. A mechanistic investigation of action potential conduction and conduction failure. , 1997, Circulation research.

[33]  V. Fast,et al.  Paradoxical Improvement of Impulse Conduction in Cardiac Tissue by Partial Cellular Uncoupling , 1997, Science.

[34]  K. Goshima,et al.  Synchronized beating of and electrotonic transmission between myocardial cells mediated by heterotypic strain cells in monolayer culture. , 1969, Experimental cell research.

[35]  J. Boineau,et al.  Microfibrosis Produces Electrical Load Variations Due to Loss of Side‐to‐Side Cell Connections; A Major Mechanism of Structural Heart Disease Arrhythmias , 1997, Pacing and clinical electrophysiology : PACE.

[36]  A. Kleber,et al.  Patterned growth of neonatal rat heart cells in culture. Morphological and electrophysiological characterization. , 1991, Circulation research.

[37]  S. Silver,et al.  Heart Failure , 1937, The New England journal of medicine.

[38]  D. Garcia-Dorado,et al.  Cardiovascular Research , 1966 .

[39]  C S Henriquez,et al.  Influence of dynamic gap junction resistance on impulse propagation in ventricular myocardium: a computer simulation study. , 2001, Biophysical journal.

[40]  M Delmar,et al.  Null Mutation of Connexin43 Causes Slow Propagation of Ventricular Activation in the Late Stages of Mouse Embryonic Development , 2001, Circulation research.

[41]  A. Hodgkin,et al.  The diffusion of radiopotassium across intercalated disks of mammalian cardiac muscle , 1966, The Journal of physiology.

[42]  R Wilders,et al.  Spatial and functional relationship between myocytes and fibroblasts in the rabbit sinoatrial node. , 1992, Journal of molecular and cellular cardiology.

[43]  J. Francis Heidlage,et al.  Influence of the Passive Anisotropic Properties on Directional Differences in Propagation Following Modification of the Sodium Conductance in Human Atrial Muscle: A Model of Reentry Based on Anisotropic Discontinuous Propagation , 1988, Circulation research.

[44]  N. Sperelakis,et al.  Gap junction uncoupling and discontinuous propagation in the heart. A comparison of experimental data with computer simulations. , 1988, Biophysical journal.

[45]  V. Fast,et al.  Anisotropic activation spread in heart cell monolayers assessed by high-resolution optical mapping. Role of tissue discontinuities. , 1996, Circulation research.

[46]  V. Fast,et al.  Block of impulse propagation at an abrupt tissue expansion: evaluation of the critical strand diameter in 2- and 3-dimensional computer models. , 1995, Cardiovascular research.

[47]  Ryozo Nagai,et al.  Gene Expression in Fibroblasts and Fibrosis: Involvement in Cardiac Hypertrophy , 2002, Circulation research.

[48]  J. Going,et al.  Expression of gap junction proteins connexin 26 and connexin 43 in normal human breast and in breast tumours , 1998, The Journal of pathology.

[49]  M. Miragoli,et al.  Coupling of Cardiac Electrical Activity Over Extended Distances by Fibroblasts of Cardiac Origin , 2003, Circulation research.

[50]  B M Salzberg,et al.  Multiple site optical recording of transmembrane voltage (MSORTV) in patterned growth heart cell cultures: assessing electrical behavior, with microsecond resolution, on a cellular and subcellular scale. , 1994, Biophysical journal.

[51]  S. Masur,et al.  Functional gap junctions in corneal fibroblasts and myofibroblasts. , 1998, Investigative ophthalmology & visual science.

[52]  J. L. Hill,et al.  Interaction of Acidosis and Increased Extracellular Potassium on Action Potential Characteristics and Conduction in Guinea Pig Ventricular Muscle , 1982, Circulation research.

[53]  F. Sjöstrand,et al.  Electron microscopy of the intercalated discs of cardiac muscle tissue , 1954, Experientia.

[54]  V. Fast,et al.  Microscopic conduction in cultured strands of neonatal rat heart cells measured with voltage-sensitive dyes. , 1993, Circulation research.

[55]  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.

[56]  R. W. Joyner,et al.  Effects of the Discrete Pattern of Electrical Coupling on Propagation through an Electrical Syncytium , 1982, Circulation research.

[57]  B. Swynghedauw,et al.  Molecular mechanisms of myocardial remodeling. , 1999, Physiological reviews.

[58]  Susan Dumps,et al.  A model study. , 1988, Nursing standard (Royal College of Nursing (Great Britain) : 1987).