Bitar Milad S, Al-Saleh Eyad, Al-Mulla Fahd
Department of Pharmacology and Toxicology, Faculty of Medicine, Kuwait University, P.O. Box 24923, Safat, Kuwait, 13110.
Life Sci. 2005 Sep 30;77(20):2552-73. doi: 10.1016/j.lfs.2005.01.033.
Insulin resistance, characterized by an inexorable decline in skeletal muscle glucose utilization and/or an excessive hepatic glucose production, constitutes a major pathogenic importance in a cluster of clinical disorders including diabetes mellitus, hypertension, dyslipidemia, central obesity and coronary artery disease. A novel concept suggests that heightened state of oxidative stress during diabetes contributes, at least in part, to the development of insulin resistance. Several key predictions of this premise were subjected to experimental testing using Goto-Kakizaki (GK) rats as a genetic animal model for non-obese type II diabetes. Euglycemic-hyperinsulinemic clamp studies with an insulin infusion index of 5 mU/kg bw/min were used to measure endogenous glucose production (EGP), glucose infusion rate (GIR), glucose disposal rate (GDR) and skeletal muscle glucose utilization index (GUI). Moreover, the status of oxidative stress as reflected by the urinary levels of isoprostane and protein carbonyl formation were also assessed as a function of diabetes. Post-absorptive basal EGP and circulating levels of insulin, glucose and free fatty acid (FFA) were elevated in GK rats, compared to their corresponding control values. In contrast, steady state GIR and GDR of the hyperglycemic/hyperinsulinemic animals were reduced, concomitantly with impaired insulin's ability to suppress EGP. Insulin stimulated [3H]-2-deoxyglucose (2-DG) uptake (a measure of glucose transport activity) by various types of skeletal muscle fibers both in vivo and in vitro (isolated muscle, cultured myoblasts) was diminished in diabetic GK rats. This diabetes-related suppression of skeletal muscle glucose utilization was associated with a decrease in insulin's ability to promote the phosphorylation of tyrosine residues of insulin receptor substrate-1 (IRS-1). Similarly, the translocation of GLUT-4 from intracellular compartment to plasma membrane in response to insulin was also reduced in these animals. Oxidative stress-based markers (e.g. urinary isoprostane, carbonyl-bound proteins) were elevated as a function of diabetes. Nullification of the heightened state of oxidative stress in the GK rats with alpha-lipoic acid resulted in a partial amelioration of the diabetes-related impairment of the in vivo and in vitro insulin actions. Collectively, the above data suggest that 1) insulin resistance in GK rats occurs at the hepatic and skeletal muscle levels, 2) muscle cell glucose transport exhibited a blunted response to insulin and it is associated with a major defect in key molecules of both GLUT-4 trafficking and insulin signaling pathways, 3) skeletal muscle insulin resistance in GK rats appears to be of genetic origin and not merely related to a paracrine or autocrine effect, since this phenomenon is also observed in cultured myoblasts over several passages and finally heightened state of oxidative stress may mediate the development of insulin resistance during diabetes.
胰岛素抵抗的特征是骨骼肌葡萄糖利用率持续下降和/或肝脏葡萄糖生成过多,在包括糖尿病、高血压、血脂异常、中心性肥胖和冠状动脉疾病在内的一系列临床疾病中具有重要的致病意义。一个新的概念表明,糖尿病期间氧化应激状态的增强至少部分促成了胰岛素抵抗的发展。利用Goto-Kakizaki(GK)大鼠作为非肥胖型II型糖尿病的遗传动物模型,对这一假设的几个关键预测进行了实验验证。采用胰岛素输注指数为5 mU/kg体重/分钟的正常血糖-高胰岛素钳夹研究来测量内源性葡萄糖生成(EGP)、葡萄糖输注率(GIR)、葡萄糖处置率(GDR)和骨骼肌葡萄糖利用指数(GUI)。此外,还评估了作为糖尿病函数的尿中异前列腺素水平和蛋白质羰基形成所反映的氧化应激状态。与相应的对照值相比,GK大鼠的空腹基础EGP以及胰岛素、葡萄糖和游离脂肪酸(FFA)的循环水平升高。相反,高血糖/高胰岛素动物的稳态GIR和GDR降低,同时胰岛素抑制EGP的能力受损。在体内和体外(分离的肌肉、培养的成肌细胞),胰岛素刺激的各种类型骨骼肌纤维对[3H]-2-脱氧葡萄糖(2-DG)的摄取(葡萄糖转运活性的一种测量方法)在糖尿病GK大鼠中减少。这种与糖尿病相关的骨骼肌葡萄糖利用抑制与胰岛素促进胰岛素受体底物-1(IRS-1)酪氨酸残基磷酸化的能力下降有关。同样,在这些动物中,胰岛素刺激下GLUT-4从细胞内区室向质膜的转位也减少。基于氧化应激的标志物(如尿中异前列腺素、羰基结合蛋白)随着糖尿病的发展而升高。用α-硫辛酸消除GK大鼠增强的氧化应激状态,导致体内和体外胰岛素作用的糖尿病相关损伤得到部分改善。总体而言,上述数据表明:1)GK大鼠的胰岛素抵抗发生在肝脏和骨骼肌水平;2)肌肉细胞葡萄糖转运对胰岛素的反应减弱,并且与GLUT-4转运和胰岛素信号通路关键分子的主要缺陷有关;3)GK大鼠的骨骼肌胰岛素抵抗似乎源于遗传,而不仅仅与旁分泌或自分泌效应有关,因为在培养的成肌细胞中经过几代也观察到这种现象;最后,增强的氧化应激状态可能介导糖尿病期间胰岛素抵抗的发展。
