Characterization of Gap Junction Channels in Adult Rabbit Atrial and Ventricular Myocardium

Abstract

Abstract For effective cardiac output, it is essential that electrical excitation spread rapidly throughout the atria and ventricles. This is effected by electrical coupling through gap junction channels at contact sites between myocytes. These channels form a low-resistance pathway between adjacent myocytes and consist of connexin proteins. The connexin family is a large multigene family, and the channels formed by different members of this family have distinct electrical and regulatory properties. We have studied gap junction channels between adult rabbit atrial and ventricular myocytes using immunocytochemical and electrophysiological methods. Gap junctions of ventricular myocytes were immunoreactive to antibodies directed against connexin43 (Cx43) and Cx45, but not to antibodies against Cx37 or Cx40. Gap junctions between atrial myocytes showed immunostaining with anti-Cx40, -Cx43, and -Cx45 antibodies, but not with anti-Cx37 antibody. Endocardial and endothelial tissue were labeled with both Cx37 and Cx40 antibodies. The conductance of rabbit myocardial gap junctions was measured using the double whole-cell voltage-clamp method. The average macroscopic junctional conductance, corrected for series resistance, of atrial and ventricular cell pairs did not differ significantly (169±146 and 175±147 nS, respectively), and both were at most only slightly sensitive to the applied transjunctional potential difference. The difference in connexin expression between atrial and ventricular myocytes was reflected in the distribution of single gap junction channel conductances. A single population of unitary channel conductances with an average of 100 pS was observed between ventricular myocyte pairs. In addition to this population, a population with an average conductance of 185 pS was present between atrial myocyte pairs. The observed difference in connexin expression between atrial and ventricular myocardium may enable differential regulation of conduction in these tissues.