Abstract
The cardiac conduction system is an extended network of excitable tissue tasked with generation and propagation of electrical impulses to signal coordinated contraction of the heart. The fidelity of this system depends on the proper spatio-temporal regulation of ion channels in myocytes throughout the conduction system. Importantly, inherited or acquired defects in a wide class of ion channels has been linked to dysfunction at various stages of the conduction system resulting in life-threatening cardiac arrhythmia. There is growing appreciation of the role that adapter and cytoskeletal proteins play in organizing ion channel macromolecular complexes critical for proper function of the cardiac conduction system. In particular, members of the ankyrin and spectrin families have emerged as important nodes for normal expression and regulation of ion channels in myocytes throughout the conduction system. Human variants impacting ankyrin/spectrin function give rise to a broad constellation of cardiac arrhythmias. Furthermore, chronic neurohumoral and biomechanical stress promotes ankyrin/spectrin loss of function that likely contributes to conduction disturbances in the setting of acquired cardiac disease. Collectively, this review seeks to bring attention to the significance of these cytoskeletal players and emphasize the potential therapeutic role they represent in a myriad of cardiac disease states.
Highlights
We aim with this review to highlight the role of the underlying romolecular complexes for regulation of ion channel activity and membrane excitability cytoskeletal elements, ankyrin and spectrin polypeptides, in organizing macroinmolecular myocytes throughout the cardiac system.and membrane excitability in complexes for regulation of conduction ion channel activity myocytes throughout the cardiac conduction system
The cardiac conduction system is a heterogeneous collection of excitable tissues that govern generation and coordinated spread of electrical activation through the heart
Differential expression of ion channels is an important determinant of the precise sequence of events beginning with impulse generation in the sinoatrial node (SAN) and ending with rapid spread of the activation wavefront through the ventricles
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Electrophysiological properties are highly heterogeneous throughout the conduction system reflecting variable ion channel (e.g., atrioventricular node and His-Purkinje system). Electrophysiological properties are highly heterogeneous throughout the conduction system reflecting variable 2ion of 14channel expression and tissue structure [2]. A large number of acquired or inherited defects in ion channels expressed in myocytes in the conduction system have been associated cardiac conduction/rhythm disturbances and arrhythmia. We aim with this review to highlight the role of the underlying the importance of associated cytoskeletal and adapter proteins in maintaining normal ion cytoskeletal elements, ankyrin and spectrin polypeptides, in organizing macchannel function [6,7,8,9]. We aim with this review to highlight the role of the underlying romolecular complexes for regulation of ion channel activity and membrane excitability cytoskeletal elements, ankyrin and spectrin polypeptides, in organizing macroinmolecular myocytes throughout the cardiac system.and membrane excitability in complexes for regulation of conduction ion channel activity myocytes throughout the cardiac conduction system
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