Caveolin-3 KO disrupts t-tubule structure and decreases t-tubular ICa density in mouse ventricular myocytes.

Simon M Bryant,Andrew F James,David M Roth,Mark B Cannell,Judy J Watson,Clive H Orchard,Cherrie H T Kong,Hanne C Gadeberg,Hemal H Patel

doi:10.1152/ajpheart.00209.2018

Abstract

Caveolin-3 (Cav-3) is a protein that has been implicated in t-tubule formation and function in cardiac ventricular myocytes. In cardiac hypertrophy and failure, Cav-3 expression decreases, t-tubule structure is disrupted, and excitation-contraction coupling is impaired. However, the extent to which the decrease in Cav-3 expression underlies these changes is unclear. We therefore investigated the structure and function of myocytes isolated from the hearts of Cav-3 knockout (KO) mice. These mice showed cardiac dilatation and decreased ejection fraction in vivo compared with wild-type control mice. Isolated KO myocytes showed cellular hypertrophy, altered t-tubule structure, and decreased L-type Ca2+ channel current (ICa) density. This decrease in density occurred predominantly in the t-tubules, with no change in total ICa, and was therefore a consequence of the increase in membrane area. Cav-3 KO had no effect on L-type Ca2+ channel expression, and C3SD peptide, which mimics the scaffolding domain of Cav-3, had no effect on ICa in KO myocytes. However, inhibition of PKA using H-89 decreased ICa at the surface and t-tubule membranes in both KO and wild-type myocytes. Cav-3 KO had no significant effect on Na+/Ca2+ exchanger current or Ca2+ release. These data suggest that Cav-3 KO causes cellular hypertrophy, thereby decreasing t-tubular ICa density.NEW & NOTEWORTHY Caveolin-3 (Cav-3) is a protein that inhibits hypertrophic pathways, has been implicated in the formation and function of cardiac t-tubules, and shows decreased expression in heart failure. This study demonstrates that Cav-3 knockout mice show cardiac dysfunction in vivo, while isolated ventricular myocytes show cellular hypertrophy, changes in t-tubule structure, and decreased t-tubular L-type Ca2+ current density, suggesting that decreased Cav-3 expression contributes to these changes in cardiac hypertrophy and failure.

Highlights

Excitation-contraction coupling (ECC) in cardiac myocytes is initiated by the action potential, which activates sarcolemmal L-type Ca2ϩ channels (LTCCs), causing Ca2ϩ influx [Ca2ϩ current (ICa)]
Western blots of heart homogenates for Cav-3 (Fig. 1A, left) and the associated densitometric analysis (Fig. 1A, right) confirmed that Cav-3 KO myocytes did not express detectable levels of Cav-3 protein compared with weight-to-tibia length ratio (WT) control myocytes
WT and Cav-3 KO mice showed no difference in heart rate under anesthesia [WT: 436 Ϯ 29 beats/min, N ϭ 6, and Cav-3 KO: 437 Ϯ 19 beats/min, N ϭ 7, not significant (NS)]

Summary

Introduction

Excitation-contraction coupling (ECC) in cardiac myocytes is initiated by the action potential, which activates sarcolemmal L-type Ca2ϩ channels (LTCCs), causing Ca2ϩ influx [Ca2ϩ current (ICa)]. ICa triggers Ca2ϩ release from adjacent sarcoplasmic reticulum (SR) via Ca2ϩ release channels [ryanodine receptors (RyRs)]. This Ca2ϩ-induced Ca2ϩ release (CICR) [20] produces local increases of cytosolic Ca2ϩ concentration [Ca2ϩ sparks [17]] that summate to form the cytosolic Ca2ϩ transient, leading to contraction. ICa, and RyR activation, occurs predominantly at specialized invaginations of the sarcolemma called t-tubules [15, 34, 40]. This arrangement achieves near-synchronous Ca2ϩ release [16], and contraction, throughout the cell. Relaxation occurs as cytosolic Ca2ϩ concentration decreases, mainly because of reuptake into the SR and by removal from the cell via the Naϩ/ Ca2ϩ exchanger (NCX) [37]

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Results

Discussion

Conclusion