Rutter G A, Theler J M, Murgia M, Wollheim C B, Pozzan T, Rizzuto R
Department of Medicine, University of Geneva, Switzerland.
J Biol Chem. 1993 Oct 25;268(30):22385-90.
The effects of stimulated Ca2+ influx on cytosolic ([Ca2+]c) or intramitochondrial free Ca2+ ([Ca2+]m) were examined in the new pancreatic beta-cell line, INS-1. [Ca2+]c was monitored by video imaging of single fura-2-loaded INS-1 cells, or in populations of cells transfected with non-targeted (cytosolic) aequorin. [Ca2+]m was measured after transfection with aequorin targeted to the mitochondria by fusion of the gene in frame with the signal peptide of cytochrome c oxidase subunit VIII. Two physiological stimuli of native beta-cells, glucose and ATP, raised [Ca2+]c in INS-1 cells largely by stimulating Ca2+ influx. Thus, glucose (20 mM) induced repetitive transient increases in [Ca2+]c (0.42 min-1, mean amplitude 229 nM above 102 nM basal). These transients were largely due to periodic stimulation of Ca2+ influx through voltage-sensitive Ca2+ channels, since they could be rapidly and reversibly blocked by chelation of external Ca2+, by addition of the hyperpolarizing agent diazoxide, or with the Ca2+ channel blocker SR 7037. ATP, by contrast, caused single transient [Ca2+]c increases, to about 300 nM above basal levels, which could be inhibited by > 90% upon external Ca2+ chelation. Challenge of aequorin-transfected cells with ATP increased [Ca2+]m to 4 microM or above, an effect blocked by EGTA. Furthermore, plasma membrane depolarization with high K+, used as a glucose surrogate to mimic, in a synchronized fashion, the influx-induced Ca2+ transients observed at the single-cell level, also increased [Ca2+]m to > 4 microM. Similar increases in [Ca2+]m were also measured in other aequorin-transfected insulin-secreting cells, RINm5F, during mobilization of internal Ca2+ with carbachol. In contrast, glucose-induced changes in [Ca2+]m were below the level of detection in INS-1 cell populations, consistent with the asynchrony of the [Ca2+]c transients induced by this nutrient at the single-cell level, and the consequent small average [Ca2+]c rise. These data are in line with the view that stimulated Ca2+ influx into excitable cells raises [Ca2+]m as efficiently as internal Ca2+ mobilization in nonexcitable cells. In the case of INS-1 and pancreatic beta-cells, this may be important both to enhance oxidative metabolism, hence fueling the secretory process, and also to maintain the production of metabolic signaling molecules.
在新的胰腺β细胞系INS-1中研究了刺激的Ca2+内流对胞质([Ca2+]c)或线粒体内游离Ca2+([Ca2+]m)的影响。通过对单个负载fura-2的INS-1细胞进行视频成像,或在转染了非靶向(胞质)水母发光蛋白的细胞群体中监测[Ca2+]c。在用细胞色素c氧化酶亚基VIII的信号肽与基因框内融合而靶向线粒体的水母发光蛋白转染后,测量[Ca2+]m。天然β细胞的两种生理刺激物葡萄糖和ATP,主要通过刺激Ca2+内流使INS-1细胞中的[Ca2+]c升高。因此,葡萄糖(20 mM)诱导[Ca2+]c出现重复性瞬时升高(0.42次/分钟,平均幅度比102 nM的基础水平高229 nM)。这些瞬时变化主要是由于通过电压敏感性Ca2+通道对Ca2+内流的周期性刺激,因为它们可被外部Ca2+的螯合、超极化剂二氮嗪的添加或Ca2+通道阻滞剂SR 7037快速且可逆地阻断。相比之下,ATP引起[Ca2+]c单次瞬时升高,比基础水平高约300 nM,在外部Ca2+螯合时可被抑制>90%。用ATP刺激转染了水母发光蛋白的细胞会使[Ca2+]m升高至4 μM或更高,这一效应被乙二醇双四乙酸(EGTA)阻断。此外,用高钾使质膜去极化,作为葡萄糖的替代物以同步方式模拟在单细胞水平观察到的内流诱导的Ca2+瞬时变化,也会使[Ca2+]m升高至>4 μM。在用卡巴胆碱动员内部Ca2+期间,在其他转染了水母发光蛋白的胰岛素分泌细胞RINm5F中也测量到了类似的[Ca2+]m升高。相比之下,葡萄糖诱导的[Ca2+]m变化在INS-1细胞群体中低于检测水平,这与该营养物质在单细胞水平诱导的[Ca2+]c瞬时变化的异步性以及随之而来的平均[Ca2+]c小幅升高一致。这些数据符合以下观点:刺激Ca2+流入可兴奋细胞会使[Ca2+]m升高,其效率与不可兴奋细胞中内部Ca2+动员相同。对于INS-1和胰腺β细胞而言,这可能在增强氧化代谢从而为分泌过程提供能量以及维持代谢信号分子的产生方面都很重要。
