Department of Internal Medicine, Henry Ford Hospital, Detroit, Michigan, United States of America.
PLoS One. 2013 Apr 15;8(4):e54436. doi: 10.1371/journal.pone.0054436. Print 2013.
Calpain is an intracellular Ca²⁺-activated protease that is involved in numerous Ca²⁺ dependent regulation of protein function in many cell types. This paper tests a hypothesis that calpains are involved in Ca²⁺-dependent increase of the late sodium current (INaL) in failing heart. Chronic heart failure (HF) was induced in 2 dogs by multiple coronary artery embolization. Using a conventional patch-clamp technique, the whole-cell INaL was recorded in enzymatically isolated ventricular cardiomyocytes (VCMs) in which INaL was activated by the presence of a higher (1 μM) intracellular [Ca²⁺] in the patch pipette. Cell suspensions were exposed to a cell- permeant calpain inhibitor MDL-28170 for 1-2 h before INaL recordings. The numerical excitation-contraction coupling (ECC) model was used to evaluate electrophysiological effects of calpain inhibition in silico. MDL caused acceleration of INaL decay evaluated by the two-exponential fit (τ₁ = 42±3.0 ms τ₂ = 435±27 ms, n = 6, in MDL vs. τ₁ = 52±2.1 ms τ₂ = 605±26 control no vehicle, n = 11, and vs. τ₁ = 52±2.8 ms τ₂ = 583±37 ms n = 7, control with vehicle, P<0.05 ANOVA). MDL significantly reduced INaL density recorded at -30 mV (0.488±0.03, n = 12, in control no vehicle, 0.4502±0.0210, n = 9 in vehicle vs. 0.166±0.05pA/pF, n = 5, in MDL). Our measurements of current-voltage relationships demonstrated that the INaL density was decreased by MDL in a wide range of potentials, including that for the action potential plateau. At the same time the membrane potential dependency of the steady-state activation and inactivation remained unchanged in the MDL-treated VCMs. Our ECC model predicted that calpain inhibition greatly improves myocyte function by reducing the action potential duration and intracellular diastolic Ca²⁺ accumulation in the pulse train.
Calpain inhibition reverses INaL changes in failing dog ventricular cardiomyocytes in the presence of high intracellular Ca²⁺. Specifically it decreases INaL density and accelerates INaL kinetics resulting in improvement of myocyte electrical response and Ca²⁺ handling as predicted by our in silico simulations.
钙蛋白酶是一种细胞内 Ca²⁺ 激活的蛋白酶,参与许多细胞类型中许多 Ca²⁺ 依赖性调节蛋白功能。本文提出了一个假设,即钙蛋白酶参与了衰竭心脏中 Ca²⁺ 依赖性晚期钠电流(INaL)的增加。通过多次冠状动脉栓塞,在 2 只狗中诱导慢性心力衰竭(HF)。使用传统的膜片钳技术,在酶解分离的心室肌细胞(VCM)中记录全细胞 INaL,其中 INaL 通过在膜片钳中存在较高(1 μM)细胞内 [Ca²⁺] 来激活。在记录 INaL 之前,细胞悬浮液用细胞通透性钙蛋白酶抑制剂 MDL-28170 孵育 1-2 小时。使用数值兴奋-收缩偶联(ECC)模型来评估钙蛋白酶抑制在计算机模拟中的电生理效应。MDL 导致 INaL 衰减的双指数拟合评估加速(τ₁=42±3.0ms τ₂=435±27ms,n=6,在 MDL 中与 τ₁=52±2.1ms τ₂=605±26ms 对照无载体,n=11,和与 τ₁=52±2.8ms τ₂=583±37ms n=7,对照有载体,P<0.05 ANOVA)。MDL 显著降低了在-30 mV 记录的 INaL 密度(在对照无载体中为 0.488±0.03,n=12,在载体中为 0.4502±0.0210,n=9,在 MDL 中为 0.166±0.05pA/pF,n=5)。我们对电流-电压关系的测量表明,在广泛的电位范围内,包括动作电位平台电位,MDL 降低了 INaL 密度。同时,在 MDL 处理的 VCM 中,稳态激活和失活的膜电位依赖性保持不变。我们的 ECC 模型预测,钙蛋白酶抑制通过降低动作电位持续时间和脉冲串期间细胞内舒张 Ca²⁺ 积累,极大地改善了心肌细胞的功能。
钙蛋白酶抑制在高细胞内 Ca²⁺ 存在下逆转衰竭犬心室肌细胞中 INaL 的变化。具体来说,它降低了 INaL 密度并加速了 INaL 动力学,从而改善了心肌细胞的电反应和 Ca²⁺ 处理,这与我们的计算机模拟预测一致。
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