Cardiac muscle cell interaction: from microanatomy to the molecular make-up of the gap junction

Abstract

Electrical coupling between cardiac muscle cells is mediated by specialised sites of plasma membrane interaction termed gap junctions, one of three types of intercellular junction of the cardiac intercalated disk. Gap junctions consist of clusters of plasma membrane channels directly linking the cytoplasmic compartments of neighbouring cells. Gap-junctional channels are constructed from connexins, a multigene family of conserved proteins. The principal connexin isoform of the mammalian heart is connexin43; other connexins, notably connexin40, connexin45 and connexin37, are also expressed but in smaller quantities. Antibodies directed against unique sequences of these molecules allow investigation of the role of gap junctions and their component connexins in relation to the electrophysiological properties of the healthy and diseased heart. Confocal laser scanning microscopy of working ventricular myocytes immunolabelled with anticonnexin43 antibodies permits highly sensitive detection of gap junctions, allowing detailed analysis of the spatial distribution of the conduction pathways from the leve1 of the cell to that of the tissue as a whole. Gap junction distribution, number and regional variations in the type of connexin expressed al1 contribute to the uniform anisotropic pattern of impulse spread characteristic of normal myocardium and the orderly, sequential contraction of the cardiac chambers. Connexin40 is preferentially expressed by myocytes of the atrioventricular conduction system and represents a specialisation facilitating fast conduction, allowing rapid distribution of the impulse throughout the working ventricle. Two major abnormalities in connexin43 gap junctions are detected in human ischaemic heart disease. First, at border zones adjacent to infarct scars, zones which are particularly prone to re-entry arrhythmia, there is marked disruption of the usual ordered distribution pattem of gap junctions. Second, a widespread downregulation of connexin43 gap junctions occurs in myocardium distant from the infarct, a change that is also found in the hypertrophic (non-ischaemic) heart. Consequent localised heterogeneous conduction and reduced conduction velocity provide an explanation for the genesis of re-entry arrhythmias. A current working hypothesis is that reduction in connexin43 gap junctions is a general pathogenetic feature of cardiac disease which predisposes the heart to arrhythrnia, and that this reduction may form part of a wider pattem of alteration in the levels of other connexin isoforms.