与 caveolin-1 缺失相关的线粒体功能改变和代谢灵活性降低。
Altered mitochondrial function and metabolic inflexibility associated with loss of caveolin-1.
机构信息
Touchstone Diabetes Center, Department of Internal Medicine, University of Texas Southwestern Medical Center, 5323 Harry Hines Boulevard, Dallas, TX 75390-8549, USA.
出版信息
Cell Metab. 2012 Feb 8;15(2):171-85. doi: 10.1016/j.cmet.2012.01.004.
Abstract
Caveolin-1 is a major structural component of raft structures within the plasma membrane and has been implicated as a regulator of cellular signal transduction with prominent expression in adipocytes. Here, we embarked on a comprehensive characterization of the metabolic pathways dysregulated in caveolin-1 null mice. We found that these mice display decreased circulating levels of total and high molecular weight adiponectin and a reduced ability to change substrate use in response to feeding/fasting conditions. Caveolin-1 null mice are extremely lean but retain muscle mass despite lipodystrophy and massive metabolic dysfunction. Hepatic gluconeogenesis is chronically elevated, while hepatic steatosis is reduced. Our data suggest that the complex phenotype of the caveolin-1 null mouse is caused by altered metabolic and mitochondrial function in adipose tissue with a subsequent compensatory response driven mostly by the liver. This mouse model highlights the central contributions of adipose tissue for system-wide preservation of metabolic flexibility.
摘要
窖蛋白-1 是质膜筏结构的主要结构成分,已被认为是细胞信号转导的调节剂,在脂肪细胞中表达明显。在这里,我们着手全面描述窖蛋白-1 缺失小鼠中失调的代谢途径。我们发现,这些小鼠表现出循环总分子量和高分子量脂联素水平降低,以及对进食/禁食条件的底物利用变化的能力降低。窖蛋白-1 缺失小鼠非常瘦,但尽管存在脂肪营养不良和大量代谢功能障碍,仍保留肌肉质量。肝糖异生持续升高,而肝脂肪变性减少。我们的数据表明,窖蛋白-1 缺失小鼠的复杂表型是由脂肪组织代谢和线粒体功能改变引起的,随后主要由肝脏驱动的代偿反应。这种小鼠模型突出了脂肪组织对全身代谢灵活性的重要贡献。
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