在胰岛素抵抗表型中,肌肉内二酰甘油会随着急性高胰岛素血症而累积。

IF 4.2 2区 医学 Q1 ENDOCRINOLOGY & METABOLISM American journal of physiology. Endocrinology and metabolism Pub Date : 2024-08-01 Epub Date: 2024-06-19 DOI:10.1152/ajpendo.00368.2023
Colleen F McKenna, Harrison D Stierwalt, Karin A Zemski Berry, Sarah E Ehrlicher, Matthew M Robinson, Simona Zarini, Darcy E Kahn, Janet K Snell-Bergeon, Leigh Perreault, Bryan C Bergman, Sean A Newsom
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引用次数: 0

摘要

骨骼肌二酰甘油(DAG)和神经酰胺的升高会损害胰岛素信号传导,酰基肉碱(acylCN)反映了脂肪酸氧化功能的受损,因此肌肉内脂质谱是胰岛素抵抗的指标。急性(即餐后)高胰岛素血症已被证明会升高健康肌肉中的血脂,并且是 2 型糖尿病(T2D)的独立风险因素。目前还不清楚急性高胰岛素血症与肌肉脂质体之间的关系是如何相互作用,从而导致或加剧胰岛素抵抗的。我们研究了急性高胰岛素血症对肌肉脂质体的影响,以帮助确定高胰岛素血症增加 T2D 风险的生理基础。耐力运动员(12 人)、久坐不动的瘦成年人(12 人)、肥胖症患者(13 人)和 T2D 患者(7 人)接受了高胰岛素血症-血糖钳夹和肌肉活检。虽然 1,2-DAG 的总波动没有明显差异,但运动员的 1,2-DAG 下降了 2%,而 T2D 患者的 1,2-DAG 上升了 53%。在钳夹期间,只有 T2D 患者的 C18 1,2-DAGs 增加,这与胰岛素敏感性呈负相关。T2D 患者的基础肌肉 C18:0 神经酰胺含量升高,但钳夹不会改变。在高胰岛素血症期间,酰基肉碱普遍降低,运动员的降幅更大,达到 80%,而 T2D 患者的降幅仅为 46%。在雄性小鼠身上也观察到了类似的波动,即急性高胰岛素血症会增加胰岛素抵抗表型中的 1,2 DAGs,并普遍降低酰肉碱。总之,急性高胰岛素血症会使胰岛素抵抗表型的肌肉中 1,2-DAG 水平升高。这表明,胰岛素敏感性低的个体在进食状态下肌肉内脂代谢可能失调,这可能会加剧胰岛素抵抗。
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Intramuscular diacylglycerol accumulates with acute hyperinsulinemia in insulin-resistant phenotypes.

Elevated skeletal muscle diacylglycerols (DAGs) and ceramides can impair insulin signaling, and acylcarnitines (acylCNs) reflect impaired mitochondrial fatty acid oxidation, thus, the intramuscular lipid profile is indicative of insulin resistance. Acute (i.e., postprandial) hyperinsulinemia has been shown to elevate lipid concentrations in healthy muscle and is an independent risk factor for type 2 diabetes (T2D). However, it is unclear how the relationship between acute hyperinsulinemia and the muscle lipidome interacts across metabolic phenotypes, thus contributing to or exacerbating insulin resistance. We therefore investigated the impact of acute hyperinsulinemia on the skeletal muscle lipid profile to help characterize the physiological basis in which hyperinsulinemia elevates T2D risk. In a cross-sectional comparison, endurance athletes (n = 12), sedentary lean adults (n = 12), and individuals with obesity (n = 13) and T2D (n = 7) underwent a hyperinsulinemic-euglycemic clamp with muscle biopsies. Although there were no significant differences in total 1,2-DAG fluctuations, there was a 2% decrease in athletes versus a 53% increase in T2D during acute hyperinsulinemia (P = 0.087). Moreover, C18 1,2-DAG species increased during the clamp with T2D only, which negatively correlated with insulin sensitivity (P < 0.050). Basal muscle C18:0 total ceramides were elevated with T2D (P = 0.029), but not altered by clamp. Acylcarnitines were universally lowered during hyperinsulinemia, with more robust reductions of 80% in athletes compared with only 46% with T2D (albeit not statistically significant, main effect of group, P = 0.624). Similar fluctuations with acute hyperinsulinemia increasing 1,2 DAGs in insulin-resistant phenotypes and universally lowering acylcarnitines were observed in male mice. In conclusion, acute hyperinsulinemia elevates muscle 1,2-DAG levels with insulin-resistant phenotypes. This suggests a possible dysregulation of intramuscular lipid metabolism in the fed state in individuals with low insulin sensitivity, which may exacerbate insulin resistance.NEW & NOTEWORTHY Postprandial hyperinsulinemia is a risk factor for type 2 diabetes and may increase muscle lipids. However, it is unclear how the relationship between acute hyperinsulinemia and the muscle lipidome interacts across metabolic phenotypes, thus contributing to insulin resistance. We observed that acute hyperinsulinemia elevates muscle 1,2-DAGs in insulin-resistant phenotypes, whereas ceramides were unaltered. Insulin-mediated acylcarnitine reductions are also hindered with high-fat feeding. The postprandial period may exacerbate insulin resistance in metabolically unhealthy phenotypes.

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来源期刊
CiteScore
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期刊介绍: The American Journal of Physiology-Endocrinology and Metabolism publishes original, mechanistic studies on the physiology of endocrine and metabolic systems. Physiological, cellular, and molecular studies in whole animals or humans will be considered. Specific themes include, but are not limited to, mechanisms of hormone and growth factor action; hormonal and nutritional regulation of metabolism, inflammation, microbiome and energy balance; integrative organ cross talk; paracrine and autocrine control of endocrine cells; function and activation of hormone receptors; endocrine or metabolic control of channels, transporters, and membrane function; temporal analysis of hormone secretion and metabolism; and mathematical/kinetic modeling of metabolism. Novel molecular, immunological, or biophysical studies of hormone action are also welcome.
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