Role of ryanodine receptor cooperativity in Ca2+-wave-mediated triggered activity in cardiomyocytes

IF 4.7 2区医学 Q1 NEUROSCIENCES

Journal of Physiology-London Pub Date : 2024-11-20 DOI:10.1113/JP286145

Mingwang Zhong, Alain Karma

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引用次数: 0

Abstract

Ca²⁺ waves are known to trigger delayed after-depolarizations that can cause malignant cardiac arrhythmias. However, modelling Ca²⁺ waves using physiologically realistic models has remained a major challenge. Existing models with low Ca²⁺ sensitivity of ryanodine receptors (RyRs) necessitate large release currents, leading to an unrealistically large Ca²⁺ transient amplitude incompatible with the experimental observations. Consequently, current physiologically detailed models of delayed after-depolarizations resort to unrealistic cell architectures to produce Ca²⁺ waves with a normal Ca²⁺ transient amplitude. Here, we address these challenges by incorporating RyR cooperativity into a physiologically detailed model with a realistic cell architecture. We represent RyR cooperativity phenomenologically through a Hill coefficient within the sigmoid function of RyR open probability. Simulations in permeabilized myocytes with high Ca²⁺ sensitivity reveal that a sufficiently large Hill coefficient is required for Ca²⁺ wave propagation via the fire–diffuse–fire mechanism. In intact myocytes, propagating Ca²⁺ waves can occur only within an intermediate Hill coefficient range. Within this range, the spark rate is neither too low, enabling Ca²⁺ wave propagation, nor too high, allowing for the maintenance of a high sarcoplasmic reticulum load during diastole of the action potential. Moreover, this model successfully replicates other experimentally observed manifestations of Ca²⁺-wave-mediated triggered activity, including phase 2 and phase 3 early after-depolarizations and high-frequency voltage–Ca²⁺ oscillations. These oscillations feature an elevated take-off potential with depolarization mediated by the L-type Ca²⁺ current. The model also sheds light on the roles of luminal gating of RyRs and the mobile buffer ATP in the genesis of these arrhythmogenic phenomena.

Key points

Existing mathematical models of Ca²⁺ waves use an excessively large Ca²⁺-release current or unrealistic diffusive coupling between release units.
Our physiologically realistic model, using a Hill coefficient in the ryanodine receptor (RyR) gating function to represent RyR cooperativity, addresses these limitations and generates organized Ca²⁺ waves at Hill coefficients ranging from ∼5 to 10, as opposed to the traditional value of 2.
This range of Hill coefficients gives a spark rate neither too low, thereby enabling Ca²⁺ wave propagation, nor too high, allowing for the maintenance of a high sarcoplasmic reticulum load during the plateau phase of the action potential.
Additionally, the model generates Ca²⁺-wave-mediated phase 2 and phase 3 early after-depolarizations, and coupled membrane voltage with Ca²⁺ oscillations mediated by the L-type Ca²⁺ current.
This study suggests that pharmacologically targeting RyR cooperativity could be a promising strategy for treating cardiac arrhythmias linked to Ca²⁺-wave-mediated triggered activity.

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雷诺丁受体合作性在 Ca2+ 波介导的心肌细胞触发活动中的作用

众所周知，Ca2+波会引发延迟后除极化，从而导致恶性心律失常。然而，使用符合生理实际的模型来模拟 Ca2+ 波仍然是一项重大挑战。现有模型对 Ca2+ 的敏感性较低，因此需要较大的释放电流，从而导致不切实际的较大 Ca2+ 瞬态振幅，这与实验观察结果不符。因此，目前延迟后去极化的生理学详细模型采用了不切实际的细胞结构，以产生具有正常 Ca2+ 瞬态振幅的 Ca2+ 波。在这里，我们通过将 RyR 合作性纳入具有现实细胞结构的生理学详细模型来应对这些挑战。我们通过 RyR 开放概率 sigmoid 函数中的希尔系数，以现象学的方式表示 RyR 合作性。在具有高 Ca2+ 敏感性的渗透肌细胞中进行的模拟显示，通过火-扩散-火机制传播 Ca2+ 波需要足够大的希尔系数。在完整的心肌细胞中，Ca2+波的传播只能在中间希尔系数范围内发生。在这一范围内，火花率既不会太低而导致 Ca2+ 波传播，也不会太高而导致在动作电位舒张期维持较高的肌质网负荷。此外，该模型还成功复制了实验观察到的 Ca2+ 波介导的触发活动的其他表现形式，包括第 2 和第 3 阶段早期后除极和高频电压-Ca2+ 振荡。这些振荡的特点是由 L 型 Ca2+ 电流介导的去极化和起飞电位升高。该模型还揭示了 RyRs 管腔门控和移动缓冲 ATP 在这些致心律失常现象中的作用。要点：现有的 Ca2+ 波数学模型使用了过大的 Ca2+ 释放电流或释放单元之间不切实际的扩散耦合。我们的模型符合生理实际，使用雷诺丁受体（RyR）门控函数中的希尔系数来表示 RyR 的合作性，从而解决了这些局限性，并在希尔系数为 5 至 10 的范围内产生有组织的 Ca2+ 波，而不是传统的 2。此外，该模型还能产生由 Ca2+ 波介导的第 2 阶段和第 3 阶段早期后除极，并将膜电压与由 L 型 Ca2+ 电流介导的 Ca2+ 振荡耦合在一起。这项研究表明，针对 RyR 合作性的药物治疗可能是治疗与 Ca2+ 波介导的触发活动有关的心律失常的一种有前途的策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Physiology-London 医学-神经科学

CiteScore

9.70

自引率

7.30%

发文量

817

审稿时长

2 months

期刊介绍： The Journal of Physiology publishes full-length original Research Papers and Techniques for Physiology, which are short papers aimed at disseminating new techniques for physiological research. Articles solicited by the Editorial Board include Perspectives, Symposium Reports and Topical Reviews, which highlight areas of special physiological interest. CrossTalk articles are short editorial-style invited articles framing a debate between experts in the field on controversial topics. Letters to the Editor and Journal Club articles are also published. All categories of papers are subjected to peer reivew. The Journal of Physiology welcomes submitted research papers in all areas of physiology. Authors should present original work that illustrates new physiological principles or mechanisms. Papers on work at the molecular level, at the level of the cell membrane, single cells, tissues or organs and on systems physiology are all acceptable. Theoretical papers and papers that use computational models to further our understanding of physiological processes will be considered if based on experimentally derived data and if the hypothesis advanced is directly amenable to experimental testing. While emphasis is on human and mammalian physiology, work on lower vertebrate or invertebrate preparations may be suitable if it furthers the understanding of the functioning of other organisms including mammals.