Aims/hypothesis Orexin/hypocretin is a hypothalamic neuropeptide that regulates motivated behaviours, such as feeding and arousal, and, importantly, is also involved in energy homeostasis. The aim of this study was to reveal the role of orexin in the regulation of insulin sensitivity for glucose metabolism. Methods Orexin knockout mice fasted overnight underwent oral glucose tolerance testing and insulin tolerance testing. The impact of orexin deficiency on insulin signalling was studied by Western blotting to measure levels of Akt phosphorylation and its upstream and downstream molecules in the hypothalamus, muscle and liver in orexin knockout mice. Results We found that orexin deficiency caused the agerelated development of impaired glucose tolerance and insulin resistance in both male mice without obesity and female mice with mild obesity, fed a normal chow diet. When maintained on a high-fat diet, these abnormalities became more pronounced exclusively in female orexin knockout mice that developed severe obesity. Insulin signalling through Akt was disrupted in peripheral tissues of middle-aged (9-month-old) but not young adult (2-to-3-month-old) orexin knockout mice fed a normal chow diet. Moreover, basal levels of hypothalamic Akt phosphorylation were abnormally elevated in orexin knockout mice at every age studied, and insulin stimulation failed to increase the level of phosphorylation. Similar abnormalities were observed with respect to GSK3β phosphorylation in the hypothalamus and peripheral tissues of middle-aged orexin knockout mice. Conclusions/interpretation Our results demonstrate a novel role for orexin in hypothalamic insulin signalling, which is likely to be responsible for preventing the development of peripheral insulin resistance with age.
Circadian rhythm is crucial for preventing hepatic insulin resistance, although the mechanism remains uncovered. Here we report that the wake-active hypothalamic orexin system plays a key role in this regulation. Wildtype mice showed that a daily rhythm in blood glucose levels peaked at the awake period; however, the glucose rhythm disappeared in orexin knockout mice despite normal feeding rhythm. Central administration of orexin A during nighttime awake period acutely elevated blood glucose levels but subsequently lowered daytime glucose levels in normal and diabetic db/db mice. The glucose-elevating and -lowering effects of orexin A were suppressed by adrenergic antagonists and hepatic parasympathectomy, respectively. Moreover, the expression levels of hepatic gluconeogenic genes, including Pepck, were increased and decreased by orexin A at nanomolar and femtomolar doses, respectively. These results indicate that orexin can bidirectionally regulate hepatic gluconeogenesis via control of autonomic balance, leading to generation of the daily blood glucose oscillation. Furthermore, during aging, orexin deficiency enhanced endoplasmic reticulum (ER) stress in the liver and caused impairment of hepatic insulin signaling and abnormal gluconeogenic activity in pyruvate tolerance test. Collectively, the daily glucose rhythm under control of orexin appears to be important for maintaining ER homeostasis, thereby preventing insulin resistance in the liver.Maintaining glucose and energy homeostasis throughout the day is essential for survival. Therefore, different metabolic functions are timely activated according to the circadian rhythm. Recently, it has also become clear that fine tuning of daily metabolic rhythms is crucial for preventing metabolic abnormalities. For instance, chronic disruption of circadian rhythm in humans, as seen in shift workers, increases the risk of obesity and type 2 diabetes (1,2), and circadian rhythms of glucose regulation are impaired in diabetic animals and patients with diabetes (3).Circadian rhythms of peripheral tissues, including liver, are entrained to the central biological clock located in the suprachiasmatic nuclei (SCN) via autonomic and hormonal pathways (4). The liver plays a pivotal role in maintaining optimal glucose levels via hepatic glucose production (HGP) and glucose uptake. The daily rhythm of HGP is regulated by the autonomic nervous system under SCN control, leading to generation of a daily rhythm in basal blood glucose levels independently of the feeding rhythm (5). The central clock is also crucial for preventing metabolic abnormalities
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