Marshall S, Olefsky J M
J Clin Invest. 1980 Oct;66(4):763-72. doi: 10.1172/JCI109914.
We have examined the effect of in vitro hyperinsulinemia on insulin binding, glucose transport, and insulin degradation in isolated rat adipocytes. When cells were incubated with insulin for 2 or 4 h at 37 degrees C, followed by washing in insulin-free buffer to remove extracellular and receptor-bound insulin, a time and dose-dependent decrease in insulin receptors was observed, which was accompanied by a reduced ability of cells to degrade insulin. Furthermore, the quantitatively predicted rightward shift in the insulin-glucose transport dose-response curve could be demonstrated. In addition to this reduction in insulin sensitivity, a striking decrease in maximal insulin-stimulated glucose transport was observed in the 4-h insulin-treated cells, indicating an abnormality distal to the insulin receptor. Thus, in vitro insulin-induced insulin resistance in adipocytes is caused by both receptor and postreceptor abnormalities. The post-receptor defect is most likely at the level of the glucose transport system per se because the insulinlike agents, spermine and antiinsulin receptor antibodies, also had a markedly reduced ability to stimulate glucose transport in 4-h insulin-treated cells. On the other hand, when cells were incubated with 100 ng/ml insulin for up to 4 h, after which time 2-deoxy glucose uptake was measured without removing buffer insulin or allowing receptor-bound insulin to dissociate, no decrease in maximal insulin-stimulated glucose transport was found. In conclusion, (a) insulin leads to a dose-dependent loss of insulin receptors in freshly isolated adipocytes accompanied by the predicted functional consequence of decreased receptors, i.e., a rightward shift in the insulin-glucose transport dose-response curve, (b) prolonged incubation with insulin causes a marked postreceptor defect in the glucose transport system, (c) maintenance of the activated state of the glucose transport system prevents the expression of the post-receptor defect, (d) the location of the postreceptor abnormality is most likely in the glucose transport system per se, and (e) insulin-induced receptor loss is accompanied by a decrease in insulin degradation.
我们研究了体外高胰岛素血症对分离的大鼠脂肪细胞中胰岛素结合、葡萄糖转运及胰岛素降解的影响。当细胞在37℃下与胰岛素孵育2或4小时,随后在无胰岛素缓冲液中洗涤以去除细胞外和受体结合的胰岛素时,观察到胰岛素受体呈时间和剂量依赖性减少,同时细胞降解胰岛素的能力也降低。此外,还可证明胰岛素 - 葡萄糖转运剂量反应曲线在定量预测上的右移。除了胰岛素敏感性降低外,在经4小时胰岛素处理的细胞中还观察到最大胰岛素刺激的葡萄糖转运显著下降,这表明在胰岛素受体下游存在异常。因此,体外胰岛素诱导的脂肪细胞胰岛素抵抗是由受体和受体后异常共同引起的。受体后缺陷很可能发生在葡萄糖转运系统本身水平,因为胰岛素样物质精胺和抗胰岛素受体抗体在经4小时胰岛素处理的细胞中刺激葡萄糖转运的能力也明显降低。另一方面,当细胞与100 ng/ml胰岛素孵育长达4小时,之后在不移除缓冲液中的胰岛素或不让受体结合的胰岛素解离的情况下测量2 - 脱氧葡萄糖摄取时,未发现最大胰岛素刺激的葡萄糖转运下降。总之,(a)胰岛素导致新鲜分离的脂肪细胞中胰岛素受体呈剂量依赖性丧失,并伴有受体减少所预测的功能后果,即胰岛素 - 葡萄糖转运剂量反应曲线右移;(b)长时间与胰岛素孵育会导致葡萄糖转运系统出现明显的受体后缺陷;(c)维持葡萄糖转运系统的激活状态可防止受体后缺陷的表现;(d)受体后异常的位置很可能就在葡萄糖转运系统本身;(e)胰岛素诱导的受体丧失伴有胰岛素降解减少。