Panten U, Zielmann S, Langer J, Zünkler B J, Lenzen S
Biochem J. 1984 Apr 1;219(1):189-96. doi: 10.1042/bj2190189.
In mouse pancreatic islets the kinetics of insulin secretion and O2 uptake in response to the non-metabolizable leucine analogue (+/-)-BCH (2-endo- aminonorbornane -2-carboxylic acid) were compared. In addition, the fuel-mobilizing effect of (+/-)-BCH was studied with a mitochondrial fraction from islets. (1) Within 2 min 20 mM-(+/-)-BCH markedly enhanced insulin release or O2 consumption by islets respiring in the absence of exogenous fuels. During prolonged exposure to 20 mM-(+/-)-BCH secretion declined more rapidly than O2 uptake. (2) L-Glutamine (10 mM) prevented the decrease of both insulin release and O2 uptake of islets exposed to 20mM-(+/-)-BCH. During the second phase of insulin release in response to 20 mM-(+/-)-BCH + 10 mM-L-glutamine, kinetics of secretion and respiration correlated closely. (3) Initial peaks were consistently seen in the (+/-)-BCH-induced secretory profiles, but never in the respiratory profiles. (4) In contrast with L-glycerol 3-phosphate, L-malate or pyruvate, L-glutamine or L-glutamate maintained low rates of oxidative phosphorylation in B-cell mitochondria. The effects of L-glutamine or L-glutamate were potentiated severalfold by (+/-)-BCH. (5) The effects of other branched-chain amino acids on oxidative phosphorylation resembled their effects on insulin release, redox state of nicotinamide nucleotides and glutamate dehydrogenase activity. (6) The results support the view that (+/-)-BCH stimulates insulin secretion via a primary enhancement of hydrogen supply to the respiratory chain of B-cell mitochondria.
在小鼠胰岛中,比较了胰岛素分泌动力学和对不可代谢的亮氨酸类似物(±)-BCH(2-内-氨基降冰片烷-2-羧酸)的氧气摄取情况。此外,用胰岛的线粒体部分研究了(±)-BCH的燃料动员作用。(1)在2分钟内,20 mM的(±)-BCH显著增强了在无外源燃料情况下呼吸的胰岛的胰岛素释放或氧气消耗。在长时间暴露于20 mM的(±)-BCH过程中,分泌比氧气摄取下降得更快。(2)L-谷氨酰胺(10 mM)可防止暴露于20 mM(±)-BCH的胰岛的胰岛素释放和氧气摄取减少。在对20 mM(±)-BCH + 10 mM - L-谷氨酰胺的胰岛素释放的第二阶段,分泌和呼吸动力学密切相关。(3)在(±)-BCH诱导的分泌曲线中始终可见初始峰值,但在呼吸曲线中从未出现。(4)与L-甘油3-磷酸、L-苹果酸或丙酮酸相反,L-谷氨酰胺或L-谷氨酸维持B细胞线粒体中低水平的氧化磷酸化速率。(±)-BCH使L-谷氨酰胺或L-谷氨酸的作用增强了几倍。(5)其他支链氨基酸对氧化磷酸化的作用类似于它们对胰岛素释放、烟酰胺核苷酸氧化还原状态和谷氨酸脱氢酶活性的作用。(6)结果支持这样的观点,即(±)-BCH通过首先增强向B细胞线粒体呼吸链的氢供应来刺激胰岛素分泌。