Activation of TFEB ameliorates dedifferentiation of arterial smooth muscle cells and neointima formation in mice with high-fat diet.

Yun-Ting Wang, Xiang Li, Jiajie Chen, Bradley K McConnell, Li Chen, Pin-Lan Li, Yang Chen, Yang Zhang
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Abstract

Autophagy is recently implicated in regulating vascular smooth muscle cell (SMC) homeostasis and in the pathogenesis of vascular remodeling. Transcription factor EB (TFEB) is a master regulator of autophagy signaling pathways. However, the molecular mechanisms and functional roles of TFEB in SMC homeostasis have not been elucidated. Here, we surveyed the ability of TFEB to regulate autophagy pathway in SMCs, and whether pharmacological activation of TFEB favors SMC homeostasis preventing dedifferentiation and pathogenic vascular remodeling. In primary cultured SMCs, TFEB activator trehalose induced nuclear translocation of TFEB and upregulation of TFEB-controlled autophagy genes leading to enhanced autophagy signaling. Moreover, trehalose suppressed serum-induced SMC dedifferentiation to synthetic phenotypes as characterized by inhibited proliferation and migration. These effects of trehalose were mimicked by ectopic upregulation of TFEB and inhibited by TFEB gene silencing. In animal experiments, partial ligation of carotid arteries induced downregulation of TFEB pathway in the media layer of these arteries. Such TFEB suppression was correlated with increased SMC dedifferentiation and aggravated high-fat diet (HFD)-induced neointima formation. Treatment of mice with trehalose reversed this TFEB pathway suppression, and prevented SMC dedifferentiation and HFD-induced neointima formation. In conclusion, our findings have identified TFEB as a novel positive regulator for autophagy pathway and cellular homeostasis in SMCs. Our data suggest that suppression of TFEB may be an initiating mechanism that promotes SMC dedifferentiation leading to accelerated neointima formation in vascular disorders associated with metabolic stress, whereas trehalose reverses these changes. These findings warrant further evaluation of trehalose in the clinical settings.

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激活 TFEB 可改善高脂饮食小鼠动脉平滑肌细胞的去分化和新生内膜的形成。
自噬最近被认为与调节血管平滑肌细胞(SMC)的平衡和血管重塑的发病机制有关。转录因子 EB(TFEB)是自噬信号通路的主调节因子。然而,TFEB 在 SMC 平衡中的分子机制和功能作用尚未阐明。在这里,我们研究了 TFEB 调节 SMC 自噬通路的能力,以及药物激活 TFEB 是否有利于 SMC 的稳态,防止其发生去分化和致病性血管重塑。在原代培养的 SMCs 中,TFEB 激活剂曲哈洛糖诱导 TFEB 核转位和 TFEB 控制的自噬基因上调,从而增强自噬信号传导。此外,曲哈洛糖还能抑制血清诱导的 SMC 向合成表型的去分化,合成表型的特点是增殖和迁移受到抑制。异位上调 TFEB 可模拟三卤糖的这些作用,而沉默 TFEB 基因则可抑制这些作用。在动物实验中,部分结扎颈动脉可诱导这些动脉介质层中的 TFEB 通路下调。这种 TFEB 抑制与 SMC 去分化增加和高脂饮食(HFD)诱导的新内膜形成加剧相关。用曲哈洛糖治疗小鼠可逆转这种 TFEB 通路抑制,并防止 SMC 再分化和高脂饮食诱导的新内膜形成。总之,我们的研究发现 TFEB 是 SMC 自噬通路和细胞稳态的新型正向调节因子。我们的数据表明,在与代谢压力相关的血管疾病中,TFEB 的抑制可能是促进 SMC 去分化导致新内膜加速形成的启动机制,而曲阿露糖可逆转这些变化。这些发现值得在临床环境中进一步评估曲哈洛糖。
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审稿时长
9 weeks
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