Rasmussen H, Zawalich K C, Zawalich W S
Institute of Molecular Medicine and Genetics, Medical College of Georgia, Augusta 30912.
Endocrinology. 1995 Feb;136(2):577-84. doi: 10.1210/endo.136.2.7835291.
Recent studies have led to the proposal that the oxidative metabolism of glucose leads to the generation of messengers, in addition to ATP, that are important in the ability of changes in extracellular glucose concentration to stimulate insulin secretion from pancreatic beta-cells. In particular, there is now evidence that glucose induces both a Ca(2+)-dependent and Ca(2+)-independent increase in phosphoinositide (PI) hydrolysis. To explore the relationship between oxidative metabolism and PI hydrolysis, we examined the effect of low concentrations (2.5 mM) of alpha-ketoisocaproate (KIC) and monomethylsuccinate (MMSucc) either alone or in combination on insulin secretion and PI hydrolysis in isolated rat pancreatic islets incubated with either no glucose, 5 mM glucose, or 20 mM glucose. A combination of KIC and MMSucc leads to a marked increase in largely (80%) Ca(2+)-independent PI hydrolysis in either the absence or presence of 5 mM glucose. When glucose is absent, this combination of substrates induces a very small and transient first phase of insulin secretion but no significant second phase of secretion. In the presence of 5 mM glucose, either KIC or MMSucc alone induces a first phase of insulin secretion with a peak secretory rate 10-fold greater than the basal rate but only a small second phase of secretion approximately 5-fold above control. However, in the presence of 5 mM glucose, the combination of KIC plus MMSucc induces a large biphasic increase in insulin secretion: peak first-phase secretion is increased 30-fold, and second-phase 40-fold. These response are comparable to those induced by 20 mM glucose and are completely inhibited by 0.5 microM nitrendipine. In contrast, KIC plus MMSucc do not enhance the insulin secretory response induced by 20 mM glucose. Previous data showed that when 20 mM glucose acts, the resulting increase in PI hydrolysis is only partially Ca2+ dependent. A reanalysis of these data shows that raising the glucose concentration from 5 to 7 mM causes a 2-fold increase in Ca(2+)-independent PI hydrolysis, and a further increase to 20 mM leads to a further 2-fold increase in Ca(2+)-dependent PI hydrolysis. These data show that these two pathways are regulated by different ranges of glucose concentration. They raise the interesting possibility that these distinct pathways have different signaling functions. In particular, raising the glucose concentration from 5 to 7 mM is known to alter the responsiveness of beta-cells to a variety of neurohumoral agonists and to tolbutamide.(ABSTRACT TRUNCATED AT 400 WORDS)
最近的研究提出,葡萄糖的氧化代谢除了产生ATP外,还会生成信使分子,这些信使分子对于细胞外葡萄糖浓度变化刺激胰腺β细胞分泌胰岛素的能力至关重要。特别是,现在有证据表明葡萄糖会诱导磷酸肌醇(PI)水解出现钙依赖性和非钙依赖性增加。为了探究氧化代谢与PI水解之间的关系,我们研究了低浓度(2.5 mM)的α-酮异己酸(KIC)和单甲基琥珀酸(MMSucc)单独或联合使用对在无葡萄糖、5 mM葡萄糖或20 mM葡萄糖条件下孵育的分离大鼠胰岛中胰岛素分泌和PI水解的影响。KIC和MMSucc联合使用会导致在无葡萄糖或存在5 mM葡萄糖的情况下,很大程度上(80%)非钙依赖性PI水解显著增加。当无葡萄糖时,这种底物组合会诱导出非常小且短暂的第一阶段胰岛素分泌,但没有明显的第二阶段分泌。在存在5 mM葡萄糖的情况下,单独使用KIC或MMSucc会诱导出第一阶段胰岛素分泌,其峰值分泌率比基础分泌率高10倍,但只有约比对照高5倍的小第二阶段分泌。然而,在存在5 mM葡萄糖的情况下,KIC加MMSucc的组合会诱导胰岛素分泌出现大幅双相增加:第一阶段峰值分泌增加30倍,第二阶段增加40倍。这些反应与20 mM葡萄糖诱导的反应相当,并且被0.5 microM尼群地平完全抑制。相比之下,KIC加MMSucc不会增强2 mM葡萄糖诱导的胰岛素分泌反应。先前的数据表明,当20 mM葡萄糖起作用时,由此导致的PI水解增加仅部分依赖于Ca2+。对这些数据的重新分析表明,将葡萄糖浓度从5 mM提高到7 mM会导致非钙依赖性PI水解增加2倍,进一步提高到20 mM会导致钙依赖性PI水解再增加2倍。这些数据表明这两条途径受不同葡萄糖浓度范围的调节。它们提出了一个有趣的可能性,即这些不同的途径具有不同的信号传导功能。特别是,已知将葡萄糖浓度从5 mM提高到7 mM会改变β细胞对多种神经体液激动剂和甲苯磺丁脲的反应性。(摘要截短至400字)
