Onuma Shinsuke, Kinoshita Saori, Shimba Shigeki, Ozono Keiichi, Michigami Toshimi, Kawai Masanobu
Department of Bone and Mineral Research, Research Institute, Osaka Women's and Children's Hospital, Izumi, Osaka 594-1101, Japan.
Department of Pediatrics, Osaka University Graduate School of Medicine, Suita, Osaka 565-0871, Japan.
Endocrinology. 2022 Sep 1;163(9). doi: 10.1210/endocr/bqac119.
The circadian clock network is an evolutionarily conserved system that regulates systemic metabolism, such as glucose homeostasis. Intestinal tissue is a pivotal organ for the regulation of glucose metabolism, mainly via glucose absorption into the circulation; however, the significance of the intestinal circadian clock network for glucose metabolism remains largely unclear. We herein utilized a mouse model in which Bmal1, a core clock gene, was deleted in an intestine-specific manner (Bmal1Int-/- mice) and demonstrated a rhythmic expression of Sglt1 with its peak at zeitgeber time (ZT) 10.7 ± 2.8 in control mice, whereas this was lost in Bmal1Int-/- mice. Mechanistically, chromatin immunoprecipitation analysis revealed rhythmic binding of CLOCK to the E-box elements in the Sglt1 gene in control mice; however, this was absent in Bmal1Int-/- mice. Accordingly, SGLT1 protein levels were decreased during the dark phase in Bmal1Int-/- mice and this was associated with impaired glucose absorption, leading to a decline in hepatic glycogen levels at ZT4, which was restored by ingestion of high-sucrose water. Additionally, when mice were starved from ZT0, greater expression of the lipolysis-related gene Pnpla2 was observed in adipose tissue of Bmal1Int-/- mice, and this was not noted when glycogen storage was restored by high-sucrose water prior to fasting, suggesting that higher Pnpla2 expression in Bmal1Int-/- mice was likely caused by lower glycogen storage. These results indicate that disruption of the intestinal circadian clock system impairs glucose absorption in the intestine and affects systemic glucose homeostasis.
昼夜节律时钟网络是一个进化上保守的系统,可调节全身代谢,如葡萄糖稳态。肠道组织是调节葡萄糖代谢的关键器官,主要通过葡萄糖吸收进入循环系统;然而,肠道昼夜节律时钟网络对葡萄糖代谢的重要性仍 largely 不清楚。我们在此利用一种小鼠模型,其中核心时钟基因 Bmal1 在肠道特异性方式下被敲除(Bmal1Int-/- 小鼠),并证明 Sglt1 在对照小鼠中具有节律性表达,其峰值在授时时间(ZT)10.7 ± 2.8,而在 Bmal1Int-/- 小鼠中这种节律性消失。从机制上讲,染色质免疫沉淀分析揭示了在对照小鼠中 CLOCK 与 Sglt1 基因中的 E-box 元件有节律性结合;然而,在 Bmal1Int-/- 小鼠中这种结合不存在。因此,Bmal1Int-/- 小鼠在黑暗期 SGLT1 蛋白水平降低,这与葡萄糖吸收受损有关,导致在 ZT4 时肝糖原水平下降,通过摄入高蔗糖水可恢复。此外,当小鼠从 ZT0 开始禁食时,在 Bmal1Int-/- 小鼠的脂肪组织中观察到脂解相关基因 Pnpla2 的表达增加,而在禁食前通过高蔗糖水恢复糖原储存时未观察到这种情况,这表明 Bmal1Int-/- 小鼠中较高的 Pnpla2 表达可能是由于较低的糖原储存引起的。这些结果表明,肠道昼夜节律时钟系统的破坏会损害肠道中的葡萄糖吸收并影响全身葡萄糖稳态。
