Cx43 hemichannel microdomain signaling at the intercalated disc enhances cardiac excitability
Maarten A.J. De Smet, … , Karin R. Sipido, Luc Leybaert
Maarten A.J. De Smet, … , Karin R. Sipido, Luc Leybaert
Published February 23, 2021
Citation Information: J Clin Invest. 2021;131(7):e137752. https://doi.org/10.1172/JCI137752.
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Research Article Cardiology Cell biology

Cx43 hemichannel microdomain signaling at the intercalated disc enhances cardiac excitability

Abstract

Cx43, a major cardiac connexin, forms precursor hemichannels that accrue at the intercalated disc to assemble as gap junctions. While gap junctions are crucial for electrical conduction in the heart, little is known about the potential roles of hemichannels. Recent evidence suggests that inhibiting Cx43 hemichannel opening with Gap19 has antiarrhythmic effects. Here, we used multiple electrophysiology, imaging, and super-resolution techniques to understand and define the conditions underlying Cx43 hemichannel activation in ventricular cardiomyocytes, their contribution to diastolic Ca2+ release from the sarcoplasmic reticulum, and their impact on electrical stability. We showed that Cx43 hemichannels were activated during diastolic Ca2+ release in single ventricular cardiomyocytes and cardiomyocyte cell pairs from mice and pigs. This activation involved Cx43 hemichannel Ca2+ entry and coupling to Ca2+ release microdomains at the intercalated disc, resulting in enhanced Ca2+ dynamics. Hemichannel opening furthermore contributed to delayed afterdepolarizations and triggered action potentials. In single cardiomyocytes, cardiomyocyte cell pairs, and arterially perfused tissue wedges from failing human hearts, increased hemichannel activity contributed to electrical instability compared with nonfailing rejected donor hearts. We conclude that microdomain coupling between Cx43 hemichannels and Ca2+ release is a potentially novel, targetable mechanism of cardiac arrhythmogenesis in heart failure.

Authors

Maarten A.J. De Smet, Alessio Lissoni, Timur Nezlobinsky, Nan Wang, Eef Dries, Marta Pérez-Hernández, Xianming Lin, Matthew Amoni, Tim Vervliet, Katja Witschas, Eli Rothenberg, Geert Bultynck, Rainer Schulz, Alexander V. Panfilov, Mario Delmar, Karin R. Sipido, Luc Leybaert

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Figure 9

Modeling-based estimations of electrical and Ca2+ consequences of single hemichannel opening.

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Modeling-based estimations of electrical and Ca2+ consequences of single...
(A) Schematic overview of electrical and Ca2+ consequences of single hemichannel opening. The 15.9 pA electrical current is a measured value; the 0.8 pA and 1.5 pA Ca2+ currents are calculated estimates using 1.0 and 1.8 mM of extracellular Ca2+, respectively. Panels B to E further explore the impact of a range of hemichannel Ca2+ currents. Note that the values given are only valid at –70 mV membrane potential and 37°C. Further modeling details can be found in the supplemental material. (B) Peak elevation of subsarcolemmal [Ca2+]i as a function of single hemichannel Ca2+ current (ICa,HC). (C) Membrane depolarization due to Ca2+ entry is associated with NCX activation. Black and red points indicate hemichannel Ca2+ current estimates, which are close to or in the plateau phase of the curve. (D) Probability of activation of RyR superclusters as a function of single hemichannel Ca2+ current. (E) Probability of Ca2+ wave propagation as a function of single hemichannel Ca2+ current.