Department of Metabolic Medicine, Osaka University Graduate School of Medicine, Suita, Osaka, Japan.
Department of Metabolic Medicine, Osaka University Graduate School of Medicine, Suita, Osaka, Japan
Diabetes. 2018 Jun;67(6):1113-1127. doi: 10.2337/db17-1032. Epub 2018 Apr 4.
Recent studies have emphasized the association of adipose oxidative stress (Fat reactive oxygen species [ROS]) with the pathogenesis of metabolic disorders in obesity. However, the causal roles of Fat ROS in metabolic disturbances in vivo remain unclear because no mouse model has been available in which oxidative stress is manipulated by targeting adipocytes. In this research, we generated two models of Fat ROS-manipulated mice and evaluated the metabolic features in diet-induced obesity. Fat ROS-eliminated mice, in which and were overexpressed in adipocytes, exhibited adipose expansion with decreased ectopic lipid accumulation and improved insulin sensitivity. Conversely, Fat ROS-augmented mice, in which glutathione was depleted specifically in adipocytes, exhibited restricted adipose expansion associated with increased ectopic lipid accumulation and deteriorated insulin sensitivity. In the white adipose tissues of these mice, macrophage polarization, tissue fibrosis, and de novo lipogenesis were significantly changed. In vitro approaches identified KDM1A-mediated attenuation of sterol-regulatory element-binding transcription factor 1 (SREBF1) transcriptional activities as the underlying mechanism for the suppression of de novo lipogenesis by oxidative stress. Thus, our study uncovered the novel roles of Fat ROS in healthy adipose expansion, ectopic lipid accumulation, and insulin resistance, providing the possibility for the adipocyte-targeting antioxidant therapy.
最近的研究强调了脂肪氧化应激(脂肪活性氧 [ROS])与肥胖症代谢紊乱发病机制的关联。然而,由于没有可用于靶向脂肪细胞来操纵氧化应激的小鼠模型,因此 Fat ROS 在体内代谢紊乱中的因果作用仍不清楚。在这项研究中,我们生成了两种 Fat ROS 操纵的小鼠模型,并评估了它们在饮食诱导肥胖中的代谢特征。脂肪 ROS 消除小鼠中 和 在脂肪细胞中过表达,表现出脂肪扩张,异位脂质积累减少,胰岛素敏感性提高。相反,脂肪 ROS 增强小鼠中,脂肪细胞中特异性耗尽谷胱甘肽,表现出脂肪扩张受限,异位脂质积累增加,胰岛素敏感性恶化。在这些小鼠的白色脂肪组织中,巨噬细胞极化、组织纤维化和从头脂肪生成发生了显著变化。体外方法确定了 KDM1A 介导的固醇调节元件结合转录因子 1(SREBF1)转录活性的衰减是氧化应激抑制从头脂肪生成的潜在机制。因此,我们的研究揭示了 Fat ROS 在健康脂肪扩张、异位脂质积累和胰岛素抵抗中的新作用,为脂肪细胞靶向抗氧化治疗提供了可能性。
