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Glucose is a ubiquitous and essential source of energy for all living organisms. Although mammals have evolved ways to convert other nutritional molecules to ATP, the preference for dietary glucose appears to be preserved. In rodents, the immediate detection of ingested glucose potently reinforces intake, hierarchically organizing behaviors towards glucose-yielding substances, and away from other types of food including other sugars. Taste is the primary sense linked to nutrient selection. Until recently, it was thought that most mammalian species utilize a single broadly tuned receptor to detect all simple sugars. Indeed, this “sweet” receptor, which comprises a heterodimer of the T1R2 and T1R3 proteins, binds multiple natural sugars (e.g., glucose, fructose, sucrose, maltose), as well as various other chemicals that yield little to no energy (e.g., low calorie sweeteners, sugar alcohols) and some d-amino acids. The neural signal originating from the sweet receptor is hardwired into brain circuits that drive eating and drinking behaviors, but it is an unreliable indicator of nutrient quality and quantity.

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Enhanced metabolic adaptations following late dark phase wheel running in high-fat diet-fed mice

Stephen P. Ashcroft, Amy M. Ehrlich, Krzysztof Burek, Logan A. Pendergrast, ... Juleen R. Zierath

Enhanced metabolic adaptations following late dark phase wheel running in high-fat diet-fed mice

Exercise interventions represent an effective strategy to prevent and treat metabolic diseases and the time-of-day-dependent effects of exercise on metabolic outcomes are becoming increasingly apparent. We aimed to study the influence of time-restricted wheel running on whole-body energy and glucose homeostasis. Male, 8-week-old, C57BL/6NTac mice were fed either a 60% high-fat diet (HFD) or a 10% low-fat diet (LFD) for 4 weeks. Following this, mice were given access to a running wheel between zeitgeber time (ZT) 12–16 (early dark phase) or ZT 20-0 (late dark phase). Sedentary mice had access to a permanently locked wheel. Mice were housed under these conditions in metabolic chambers for 4 weeks in which LFD and HFD conditions were maintained. Following the exercise intervention, body composition and glucose tolerance were assessed. Wheel running during either the early or late dark phase resulted in metabolic improvements such as attenuation in body weight gain, enhanced glucose tolerance and reduced ectopic lipid deposition. However, late dark phase exercise resulted in a greater reduction in body weight gain, as well as enhanced metabolic flexibility and insulin sensitivity. Our data suggest that late dark phase versus early dark phase exercise confers greater metabolic adaptations in HFD-fed mice.

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Enhanced metabolic adaptations following late dark phase wheel running in high-fat diet-fed mice

Stephen P. Ashcroft, Amy M. Ehrlich, Krzysztof Burek, Logan A. Pendergrast, ... Juleen R. Zierath

Enhanced metabolic adaptations following late dark phase wheel running in high-fat diet-fed mice

Exercise interventions represent an effective strategy to prevent and treat metabolic diseases and the time-of-day-dependent effects of exercise on metabolic outcomes are becoming increasingly apparent. We aimed to study the influence of time-restricted wheel running on whole-body energy and glucose homeostasis. Male, 8-week-old, C57BL/6NTac mice were fed either a 60% high-fat diet (HFD) or a 10% low-fat diet (LFD) for 4 weeks. Following this, mice were given access to a running wheel between zeitgeber time (ZT) 12–16 (early dark phase) or ZT 20-0 (late dark phase). Sedentary mice had access to a permanently locked wheel. Mice were housed under these conditions in metabolic chambers for 4 weeks in which LFD and HFD conditions were maintained. Following the exercise intervention, body composition and glucose tolerance were assessed. Wheel running during either the early or late dark phase resulted in metabolic improvements such as attenuation in body weight gain, enhanced glucose tolerance and reduced ectopic lipid deposition. However, late dark phase exercise resulted in a greater reduction in body weight gain, as well as enhanced metabolic flexibility and insulin sensitivity. Our data suggest that late dark phase versus early dark phase exercise confers greater metabolic adaptations in HFD-fed mice.

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