Ang Guo scite author profile

Rationale: The transverse tubule (T-tubule) system is the ultrastructural substrate for excitation-contraction coupling in ventricular myocytes; T-tubule disorganization and loss are linked to decreased contractility in end stage heart failure (HF). Objective: We sought to examine (1) whether pathological T-tubule remodeling occurs early in compensated hypertrophy and, if so, how it evolves during the transition from hypertrophy to HF; and (2) the role of junctophilin-2 in T-tubule remodeling. Methods and Results: We investigated T-tubule remodeling in relation to ventricular function during HF progression using state-of-the-art confocal imaging of T-tubules in intact hearts, using a thoracic aortic banding rat HF model. We developed a quantitative T-tubule power (TT power ) index to represent the integrity of T-tubule structure. We found that discrete local loss and global reorganization of the T-tubule system (leftward shift of TT power histogram) started early in compensated hypertrophy in left ventricular (LV) myocytes, before LV dysfunction, as detected by echocardiography. With progression from compensated hypertrophy to early and late HF, T-tubule remodeling spread from the LV to the right ventricle, and TT power histograms of both ventricles gradually shifted leftward. The mean LV TT power showed a strong correlation with ejection fraction and heart weight to body weight ratio. Over the progression to HF, we observed a gradual reduction in the expression of a junctophilin protein (JP-2) implicated in the formation of T-tubule/sarcoplasmic reticulum junctions. Furthermore, we found that JP-2 knockdown by gene silencing reduced T-tubule structure integrity in cultured adult ventricular myocytes. Conclusions: T-tubule remodeling in response to thoracic aortic banding stress begins before echocardiographically detectable LV dysfunction and progresses over the development of overt structural heart disease. LV T-tubule remodeling is closely associated with the severity of cardiac hypertrophy and predicts LV function. Thus, T-tubule remodeling may constitute a key mechanism underlying the transition from compensated hypertrophy to HF. (Circ Res. 2010;107:520-531.)Key Words: T-tubule Ⅲ myocardial remodeling Ⅲ hypertrophy Ⅲ heart failure Ⅲ confocal microscopy T he transverse tubules (T-tubules) are orderly invaginations of surface membrane along the Z-line regions, with regular spacing (Ϸ2 m) along the longitudinal axis of mammalian ventricular myocytes. The widely distributed, highly organized T-tubule system is essential for rapid electric excitation, initiation and synchronous triggering of sarcoplasmic reticulum (SR) Ca 2ϩ release, and, therefore, coordinated contraction of each contractile unit throughout the entire cytoplasm. The T-tubule system is thus an important determinant of cardiac cell function. [1][2][3] Heart failure (HF) is characterized by reduction of myocyte contractile function and defects in Ca 2ϩ handling (eg, blunted and dyssynchronous SR Ca 2ϩ release) in myocytes from HF models (includin...

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Carvedilol and its new analogs suppress arrhythmogenic store overload–induced Ca2+ release

Zhou

Xiao

Jiang

et al. 2011

Nat Med

226

257

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Carvedilol is one of the most effective beta-blockers for preventing ventricular tachyarrhythmias (VTs) in heart failure (HF), but the mechanisms underlying its favorable anti-arrhythmic benefits remain unclear. Spontaneous Ca2+ waves, also termed store-overload-induced Ca2+ release (SOICR), are known to evoke VTs in patients with HF. Here we show that carvedilol is the only beta-blocker that effectively suppresses SOICR by directly reducing the open duration of the cardiac ryanodine receptor (RyR2). This unique anti-SOICR activity of carvedilol combined with its beta-blocking activity likely contributes to its favorable anti-arrhythmic effect. To allow individual and optimal titration of these beneficial activities, we developed a novel SOICR-inhibiting, minimally-beta-blocking carvedilol analogue VK-II-86. We found that VK-II-86 alone prevented stress-induced VTs in RyR2 mutant mice, and was more effective when combined with a selective beta-blocker metoprolol or bisoprolol. Thus, SOICR inhibition combined with optimal beta-blockade presents a new, promising and potentially patient-tailorable anti-arrhythmic approach.

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The ryanodine receptor store-sensing gate controls Ca2+ waves and Ca2+-triggered arrhythmias

Chen

Wang

Chen

et al. 2014

Nat Med

180

244

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Spontaneous Ca2+ release from intracellular stores is important for various physiological and pathological processes. In cardiac muscle cells, spontaneous store overload-induced Ca2+ release (SOICR) can result in Ca2+ waves, a major cause of ventricular tachyarrhythmias (VTs) and sudden death. The molecular mechanism underlying SOICR has been a mystery for decades. Here, we show that a point mutation E4872A in the helix bundle crossing (the proposed gate) of the cardiac ryanodine receptor (RyR2) completely abolishes luminal, but not cytosolic, RyR2 Ca2+ activation. Introducing metal-binding histidines at this site converts RyR2 into a luminal Ni2+ gated channel. Mouse hearts harboring an RyR2 mutation at this site (E4872Q+/−) are resistant to store overload-induced Ca2+ waves and completely protected against Ca2+-triggered VTs. These data show that the RyR2 gate directly senses store Ca2+, explaining RyR2 store Ca2+ regulation, Ca2+ wave initiation, and Ca2+-triggered arrhythmias. This novel store-sensing gate structure is conserved in all RyRs and inositol 1,4,5-trisphosphate receptors.

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Emerging mechanisms of T-tubule remodelling in heart failure

et al. 2013

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Cardiac excitation-contraction coupling occurs primarily at the sites of transverse (T)-tubule/sarcoplasmic reticulum junctions. The orderly T-tubule network guarantees the instantaneous excitation and synchronous activation of nearly all Ca(2+) release sites throughout the large ventricular myocyte. Because of the critical roles played by T-tubules and the array of channels and transporters localized to the T-tubule membrane network, T-tubule architecture has recently become an area of considerable research interest in the cardiovascular field. This review will focus on the current knowledge regarding normal T-tubule structure and function in the heart, T-tubule remodelling in the transition from compensated hypertrophy to heart failure, and the impact of T-tubule remodelling on myocyte Ca(2+) handling function. In the last section, we discuss the molecular mechanisms underlying T-tubule remodelling in heart disease.

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Ang Guo

T-Tubule Remodeling During Transition From Hypertrophy to Heart Failure

Carvedilol and its new analogs suppress arrhythmogenic store overload–induced Ca2+ release

The ryanodine receptor store-sensing gate controls Ca2+ waves and Ca2+-triggered arrhythmias

Emerging mechanisms of T-tubule remodelling in heart failure

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