Gap junctional channels in adult mammalian sinus nodal cells. Immunolocalization and electrophysiology

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Circulation Research. 1992;71:229-239

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ARTICLES

Gap junctional channels in adult mammalian sinus nodal cells. Immunolocalization and electrophysiology

JM Anumonwo, HZ Wang, E Trabka-Janik, B Dunham, RD Veenstra, M Delmar and J Jalife
Department of Pharmacology, SUNY Health Science Center, Syracuse 13210.

The subcellular mechanism of cell-to-cell communication in the natural pacemaker region of the mammalian heart was studied using electrophysiological and immunofluorescence techniques in isolated pairs of rabbit sinus nodal cells. By measuring whole-cell currents using a double patch-clamp approach, it was demonstrated that communication in the sinus node is mediated through gap junctional channels similar to those in other types of adult cardiac cell pairs. Macroscopic sinus nodal junctional resistance had a mean value of 387.9 +/- 97.1 M omega (mean +/- SEM, n = 10) and was greatly increased by superfusion with alkanols. Single-channel junctional conductance could be resolved in three cell pairs. Given their high membrane resistance (1.16 +/- 0.32 G omega, n = 12), the electrical coupling provided by as few as three gap junctional channels between nodal cells will allow for pacemaker synchronization. Further evidence for the presence of the channels was obtained from immunofluorescent double-labeling of desmin and the gap junction protein (connexin43) in sinus nodal tissue as well as in cultured sinus nodal cells. Using antisera against residues 243- 257 of the connexin43 protein, a specific staining at the site of cell- to-cell apposition was demonstrated. These data provide direct evidence in favor of electronic coupling as the means for achieving pacemaker synchronization in the rabbit sinus node.

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				Y. Yamamoto, M. F Klemm, F. R Edwards, and H. Suzuki Intercellular electrical communication among smooth muscle and endothelial cells in guinea-pig mesenteric arterioles J. Physiol., August 15, 2001; 535(1): 181 - 195. [Abstract] [Full Text] [PDF]

				S. Verheule, M. J. A. van Kempen, S. Postma, M. B. Rook, and H. J. Jongsma Gap junctions in the rabbit sinoatrial node Am J Physiol Heart Circ Physiol, May 1, 2001; 280(5): H2103 - H2115. [Abstract] [Full Text] [PDF]

				D. J. Huelsing, A. E. Pollard, and K. W. Spitzer Transient outward current modulates discontinuous conduction in rabbit ventricular cell pairs Cardiovasc Res, March 1, 2001; 49(4): 779 - 789. [Abstract] [Full Text] [PDF]

				M.R. Boyett, H. Honjo, and I. Kodama The sinoatrial node, a heterogeneous pacemaker structure Cardiovasc Res, September 1, 2000; 47(4): 658 - 687. [Abstract] [Full Text] [PDF]

				S. R. Coppen, I. Kodama, M. R. Boyett, H. Dobrzynski, Y. Takagishi, H. Honjo, H.-I Yeh, and N. J. Severs Connexin45, a Major Connexin of the Rabbit Sinoatrial Node, Is Co-expressed with Connexin43 in a Restricted Zone at the Nodal�Crista Terminalis Border J. Histochem. Cytochem., July 1, 1999; 47(7): 907 - 918. [Abstract] [Full Text]

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				S.G. Priori, J. Barhanin, R.N.W. Hauer, W. Haverkamp, H.J. Jongsma, A.G. Kleber, W.J. McKenna, D.M. Roden, Y. Rudy, K. Schwartz, et al. Genetic and molecular basis of cardiac arrhythmias: Impact on clinical management Eur. Heart J., February 1, 1999; 20(3): 174 - 195. [PDF]

				M. Yamamoto, H. Honjo, R. Niwa, and I. Kodama Low-frequency extracellular potentials recorded from the sinoatrial node Cardiovasc Res, August 1, 1998; 39(2): 360 - 372. [Abstract] [Full Text] [PDF]

				E. E. Verheijck, A. Wessels, A. C. G. van Ginneken, J. Bourier, M. W. M. Markman, J. L. M. Vermeulen, J. M. T. de Bakker, W. H. Lamers, T. Opthof, and L. N. Bouman Distribution of Atrial and Nodal Cells Within the Rabbit Sinoatrial Node : Models of Sinoatrial Transition Circulation, April 28, 1998; 97(16): 1623 - 1631. [Abstract] [Full Text] [PDF]

				K. F. Kwong, R. B. Schuessler, K. G. Green, J. G. Laing, E. C. Beyer, J. P. Boineau, and J. E. Saffitz Differential Expression of Gap Junction Proteins in the Canine Sinus Node Circ. Res., March 23, 1998; 82(5): 604 - 612. [Abstract] [Full Text] [PDF]

				E. E. Verheijck, R. Wilders, R. W. Joyner, D. A. Golod, R. Kumar, H. J. Jongsma, L. N. Bouman, and A. C.G. v. Ginneken Pacemaker Synchronization of Electrically Coupled Rabbit Sinoatrial Node Cells J. Gen. Physiol., January 1, 1998; 111(1): 95 - 112. [Abstract] [Full Text] [PDF]

				I. t. Velde, B. de Jonge, E.E. Verheijck, M.J.A. van Kempen, L. Analbers, D. Gros, and H.J. Jongsma Spatial Distribution of Connexin43, the Major Cardiac Gap Junction Protein, Visualizes the Cellular Network for Impulse Propagation From Sinoatrial Node to Atrium Circ. Res., May 1, 1995; 76(5): 802 - 811. [Abstract] [Full Text]

				R. Gourdie, N. Severs, C. Green, S Rothery, P Germroth, and R. Thompson The spatial distribution and relative abundance of gap-junctional connexin40 and connexin43 correlate to functional properties of components of the cardiac atrioventricular conduction system J. Cell Sci., January 8, 1993; 105(4): 985 - 991. [Abstract] [PDF]

				D. Vaidya, H. S. Tamaddon, C. W. Lo, S. M. Taffet, M. Delmar, G. E. Morley, and J. Jalife Null Mutation of Connexin43 Causes Slow Propagation of Ventricular Activation in the Late Stages of Mouse Embryonic Development Circ. Res., June 8, 2001; 88(11): 1196 - 1202. [Abstract] [Full Text] [PDF]