Berlin J R, Bassani J W, Bers D M
Bockus Research Institute, Graduate Hospital, Philadelphia, Pennsylvania 19146.
Biophys J. 1994 Oct;67(4):1775-87. doi: 10.1016/S0006-3495(94)80652-6.
Intracellular passive Ca2+, buffering was measured in voltage-clamped rat ventricular myocytes. Cells were loaded with indo-1 (K+ salt) to an estimated cytosolic concentration of 44 +/- 5 microM (Mean +/- SEM, n = 5), and accessible cell volume was estimated to be 24.5 +/- 3.6 pl. Ca2+ transport by the sarcoplasmic reticulum (SR) Ca-ATPase and sarcolemmal Na-Ca exchange was inhibited by treatment with thapsigargin and Na-free solutions, respectively. Extracellular [Ca2+] was maintained at 10 mM and, in some experiments, the mitochondrial uncoupler "1799" was used to assess the degree of mitochondrial Ca2+ uptake. To perform single cell titrations, intracellular Ca2+ ([Ca2+]i) was increased progressively by a train of depolarizing voltage clamp pulses from -40 to +10 mV. The total Ca2+ gain with each pulse was calculated by integration of the Ca current and then analyzed as a function of the rapid change in [Ca2+]i during the pulse. In the range of [Ca2+]i from 0.1 to 2 microM, overall cell buffering was well described as a single lumped Michaelis-Menten type species with an apparent dissociation constant, KD, of of 0.63 +/- 0.07 microM (n = 5) and a binding capacity, Bmax, of 162 +/- 15 mumol/l cell H2O. Correction for buffering attributable to cytosolic indo-1 gives intrinsic cytosolic Ca2+ buffering parameters of KD = 0.96 +/- 0.18 microM and Bmax = 123 +/- 18 mumol/l cell H2O. The fast Ca2+ buffering measured in this manner agrees reasonably with the characteristics of known rapid Ca buffers (e.g., troponin C, calmodulin, and SR Ca-ATPase), but is only about half of the total Ca2+ buffering measured at equilibrium. Inclusion of slow Ca buffers such as the Ca/Mg sites on troponin C and myosin can account for the differences between fast Ca2+ buffering in phase with the Ca current measured in the present experiments and equilibrium Ca2+ buffering. The present data indicate that a rapid rise of [Ca2+]i from 0.1 to 1 microM during a contraction requires approximately 50 microM Ca2+ to be added to the cytosol.
在电压钳制的大鼠心室肌细胞中测量细胞内被动Ca²⁺缓冲情况。用indo-1(钾盐)将细胞加载至估计的胞质浓度为44±5微摩尔(平均值±标准误,n = 5),可及细胞体积估计为24.5±3.6皮升。分别用毒胡萝卜素和无钠溶液处理来抑制肌浆网(SR)Ca-ATP酶和肌膜钠钙交换的Ca²⁺转运。细胞外[Ca²⁺]维持在10毫摩尔,在一些实验中,用线粒体解偶联剂“1799”来评估线粒体Ca²⁺摄取程度。为进行单细胞滴定,通过一系列从 -40到 +10毫伏的去极化电压钳制脉冲逐步增加细胞内Ca²⁺([Ca²⁺]i)。每个脉冲的总Ca²⁺增加量通过Ca电流积分计算,然后作为脉冲期间[Ca²⁺]i快速变化的函数进行分析。在[Ca²⁺]i从0.1到2微摩尔的范围内,整体细胞缓冲很好地描述为单一的集总米氏类型物质,表观解离常数KD为0.63±0.07微摩尔(n = 5),结合容量Bmax为162±15微摩尔/升细胞水。对由胞质indo-1引起的缓冲进行校正后,得到固有胞质Ca²⁺缓冲参数KD = 0.96±0.18微摩尔和Bmax = 123±18微摩尔/升细胞水。以这种方式测量的快速Ca²⁺缓冲与已知快速Ca缓冲剂(如肌钙蛋白C、钙调蛋白和SR Ca-ATP酶)的特征合理相符,但仅约为平衡时测量的总Ca²⁺缓冲的一半。包括肌钙蛋白C和肌球蛋白上的Ca/Mg位点等慢Ca缓冲剂可以解释本实验中与Ca电流同相的快速Ca²⁺缓冲和平衡Ca²⁺缓冲之间的差异。目前的数据表明,收缩期间[Ca²⁺]i从0.1快速升至1微摩尔需要向胞质中添加约50微摩尔Ca²⁺。