胰岛素抵抗的细胞机制:与炎症的潜在联系。

G Perseghin, K Petersen, G I Shulman
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引用次数: 273

摘要

胰岛素抵抗是2型糖尿病发病机制的关键特征,可在临床高血糖发病前10-20年被发现。胰岛素抵抗是由于外周靶组织对胰岛素刺激的反应能力降低。特别是,胰岛素刺激的肌糖原合成受损在胰岛素抵抗中起重要作用。葡萄糖转运(GLUT4)、磷酸化(己糖激酶)和储存(糖原合成酶)是调节胰岛素刺激的肌肉葡萄糖代谢的三个潜在的速率控制步骤,这三个步骤都被认为是导致2型糖尿病患者胰岛素抵抗的主要缺陷。使用(13)C/(31)P磁共振波谱(MRS),我们证明了胰岛素刺激的肌肉葡萄糖运输活动的缺陷是速率控制缺陷。使用类似的(13)C/(31)P MRS方法,我们也证明了脂肪酸导致人类胰岛素抵抗是由于胰岛素刺激的肌肉葡萄糖转运活性降低,这可能归因于胰岛素刺激的irs -1相关磷脂酰肌醇3-激酶活性降低,这是胰岛素刺激的葡萄糖转运到肌肉的必要步骤。此外,我们最近提出,胰岛素刺激的肌肉葡萄糖转运活性的这种缺陷可能是由于丝氨酸激酶级联的激活,涉及蛋白激酶C θ和ikk - β,它们是组织炎症的关键下游介质。最后,我们提出,任何导致细胞内脂质(脂肪酸代谢物)含量增加的扰动,如线粒体脂肪酸氧化的获得性或遗传性缺陷,脂肪细胞脂肪代谢的缺陷,或仅仅是由于能量摄入增加而导致脂肪输送到肌肉/肝脏的增加,都将通过这一最终的共同途径导致胰岛素抵抗。了解胰岛素抵抗的这些关键细胞机制将有助于阐明治疗2型糖尿病的新靶点。
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Cellular mechanism of insulin resistance: potential links with inflammation.

Insulin resistance is a pivotal feature in the pathogenesis of type 2 diabetes, and it may be detected 10-20 y before the clinical onset of hyperglycemia. Insulin resistance is due to the reduced ability of peripheral target tissues to respond properly to insulin stimulation. In particular, impaired insulin-stimulated muscle glycogen synthesis plays a significant role in insulin resistance. Glucose transport (GLUT4), phosphorylation (hexokinase) and storage (glycogen synthase) are the three potential rate-controlling steps regulating insulin-stimulated muscle glucose metabolism, and all three have been implicated as being the major defects responsible for causing insulin resistance in patients with type 2 diabetes. Using (13)C/(31)P magnetic resonance spectroscopy (MRS), we demonstrate that a defect in insulin-stimulated muscle glucose transport activity is the rate-controlling defect. Using a similar (13)C/(31)P MRS approach, we have also demonstrated that fatty acids cause insulin resistance in humans due to a decrease in insulin-stimulated muscle glucose transport activity, which could be attributed to reduced insulin-stimulated IRS-1-associated phosphatidylinositol 3-kinase activity, a required step in insulin-stimulated glucose transport into muscle. Furthermore, we have recently proposed that this defect in insulin-stimulated muscle glucose transport activity may be due to the activation of a serine kinase cascade involving protein kinase C theta and IKK-beta, which are key downstream mediators of tissue inflammation. Finally, we propose that any perturbation that leads to an increase in intramyocellular lipid (fatty acid metabolites) content such as acquired or inherited defects in mitochondrial fatty acid oxidation, defects in adipocyte fat metabolism or simply increased fat delivery to muscle/liver due to increased energy intake will lead to insulin resistance through this final common pathway. Understanding these key cellular mechanisms of insulin resistance should help elucidate new targets for treating type 2 diabetes.

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