[Cardiac arrhythmias in targeted connexin deficient mice: significance for the arrhythmia field].

Intercellular communication can be mediated by gap junction channels. One channel is composed of two hexameric hemichannels which consist of six polypeptide subunits called connexines (Cx). Three different connexines were documented in the cardiac myocytes: Cx40, Cx43 and Cx45. The labeling by number represents the rounded, molecular mass of the amino acid sequences given in kD. Identical connexons form homotypic channels different connexons can form heterotypic channels. Each channel type has specific properties regarding permeability and electrical conductance. Beside a typical age-dependent alignment of gap junction channels on the surface of the cardiac myocytes, regional distribution of the different connexins is different at distinct parts of the mouse heart. The ventricular working myocardium is characterized by Cx43, whereas Cx40 and Cx45 were not found in this region. In the atria as well as in the conduction system, Cx40 is the most frequently expressed. Cx45 appears to form a border zone between conductive and the surrounding working myocardium. In line with the localization and the conduction properties of distinct homotypic gap junction channels, the Cx43 deficient mouse is suitable for analysis of ventricular arrhythmias and the Cx40 deficient mouse primarily for studies of atrial arrhythmias. Increased ventricular conduction velocity and increased ventricular vulnerability were observed in the presence of a decreased number and density of Cx43 gap junction channels. This observation, however, is controversially discussed. Cx40 deficiency induces an impairment of the sinuatrial, intraatrial and atrioventricular conduction properties and is associated with an increased atrial vulnerability. Transgenic mouse models and new mapping techniques for detection of the electrical wavefront propagation provide new insights into the mechanisms of arrhythmogenesis. Geneticists, clinicians and basic researchers need to collaborate in order to explore the clinical relevance of the new mouse models and their use for molecular medicine.