Circadian desynchrony and glucose metabolism

IF 8.3 1区 医学 Q1 ENDOCRINOLOGY & METABOLISM
Esther M. Speksnijder, Peter H. Bisschop, Sarah E. Siegelaar, Dirk Jan Stenvers, Andries Kalsbeek
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Abstract

The circadian timing system controls glucose metabolism in a time-of-day dependent manner. In mammals, the circadian timing system consists of the main central clock in the bilateral suprachiasmatic nucleus (SCN) of the anterior hypothalamus and subordinate clocks in peripheral tissues. The oscillations produced by these different clocks with a period of approximately 24-h are generated by the transcriptional-translational feedback loops of a set of core clock genes. Glucose homeostasis is one of the daily rhythms controlled by this circadian timing system. The central pacemaker in the SCN controls glucose homeostasis through its neural projections to hypothalamic hubs that are in control of feeding behavior and energy metabolism. Using hormones such as adrenal glucocorticoids and melatonin and the autonomic nervous system, the SCN modulates critical processes such as glucose production and insulin sensitivity. Peripheral clocks in tissues, such as the liver, muscle, and adipose tissue serve to enhance and sustain these SCN signals. In the optimal situation all these clocks are synchronized and aligned with behavior and the environmental light/dark cycle. A negative impact on glucose metabolism becomes apparent when the internal timing system becomes disturbed, also known as circadian desynchrony or circadian misalignment. Circadian desynchrony may occur at several levels, as the mistiming of light exposure or sleep will especially affect the central clock, whereas mistiming of food intake or physical activity will especially involve the peripheral clocks. In this review, we will summarize the literature investigating the impact of circadian desynchrony on glucose metabolism and how it may result in the development of insulin resistance. In addition, we will discuss potential strategies aimed at reinstating circadian synchrony to improve insulin sensitivity and contribute to the prevention of type 2 diabetes.

Abstract Image

昼夜节律不同步与葡萄糖代谢
昼夜节律定时系统以依赖时间的方式控制葡萄糖代谢。在哺乳动物中,昼夜节律计时系统由下丘脑前部双侧簇上核(SCN)中的主要中央时钟和外周组织中的从属时钟组成。这些不同时钟产生的周期约为 24 小时的振荡是由一组核心时钟基因的转录-翻译反馈回路产生的。葡萄糖稳态是这种昼夜节律定时系统控制的日节律之一。SCN 中的中央起搏器通过向下丘脑中枢的神经投射来控制葡萄糖平衡,而下丘脑中枢则控制着进食行为和能量代谢。利用肾上腺糖皮质激素和褪黑激素等激素以及自主神经系统,SCN 可调节葡萄糖生成和胰岛素敏感性等关键过程。肝脏、肌肉和脂肪组织等组织中的外周时钟可增强和维持这些 SCN 信号。在最佳状态下,所有这些时钟都与行为和环境的光/暗周期同步和一致。当内部计时系统受到干扰时,对葡萄糖代谢的负面影响就会显现出来,这也被称为昼夜节律不同步或昼夜节律失调。昼夜节律不同步可能发生在多个层面,因为光照或睡眠的时间错配尤其会影响中枢时钟,而食物摄入或体力活动的时间错配则尤其涉及外周时钟。在这篇综述中,我们将总结研究昼夜节律不同步对糖代谢的影响以及如何导致胰岛素抵抗的文献。此外,我们还将讨论旨在恢复昼夜节律同步以改善胰岛素敏感性并有助于预防 2 型糖尿病的潜在策略。
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来源期刊
Journal of Pineal Research
Journal of Pineal Research 医学-内分泌学与代谢
CiteScore
17.70
自引率
4.90%
发文量
66
审稿时长
1 months
期刊介绍: The Journal of Pineal Research welcomes original scientific research on the pineal gland and melatonin in vertebrates, as well as the biological functions of melatonin in non-vertebrates, plants, and microorganisms. Criteria for publication include scientific importance, novelty, timeliness, and clarity of presentation. The journal considers experimental data that challenge current thinking and welcomes case reports contributing to understanding the pineal gland and melatonin research. Its aim is to serve researchers in all disciplines related to the pineal gland and melatonin.
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