Rodent models to study the metabolic effects of shiftwork in humans

Opperhuizen, Anne-Loes; Kerkhof, Linda W M van; Proper, Karin I.; Rodenburg, Wendy; Kalsbeek, Andries

doi:10.3389/fphar.2015.00050

Cited by 73 publications

(77 citation statements)

References 94 publications

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“…Shift workers who work from 10 pm to 6 am make up about 20% of working force in modern society (Antunes et al, 2010) and have a higher prevalence of obesity and heart disease (Karlsson et al, 2001; Kubo et al, 2011; Suwazono et al, 2008). Dim light at night or prolonged daily light exposure promotes obesity and metabolic disorders in animal models (Aubrecht et al, 2015; Kooijman et al, 2015; Opperhuizen et al, 2015). Housing mice under constant light caused arrhythmicity in locomotor activity, increased food intake, reduced energy expenditure, increased body fat mass, and impaired insulin sensitivity (Coomans et al, 2013a; Shi et al, 2013).…”

Section: Evidence Supporting a Role Of Central Clock In Energy Metabomentioning

confidence: 99%

Central Circadian Clock Regulates Energy Metabolism

Ding¹,

Gong²,

Eckel‐Mahan³

et al. 2018

Advances in Experimental Medicine and Biology

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Our body not only responds to environmental changes but also anticipates them. The light and dark cycle with the period of about 24 hours is a recurring environmental change that determines the diurnal variation in food availability and safety from predators in nature. As a result, the circadian clock is evolved in most animals to align locomotor behaviors and energy metabolism with the light cue. The central circadian clock in mammals is located at the suprachiasmatic nucleus (SCN) of the hypothalamus in the brain. We here review the molecular and anatomic architecture of the central circadian clock in mammals; describe the experimental and observational evidence that suggests a critical role of the central circadian clock in shaping systemic energy metabolism; and discuss the involvement of endocrine factors, neuropeptides, and the autonomic nervous system in the metabolic functions of the central circadian clock.

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Section: Evidence Supporting a Role Of Central Clock In Energy Metabomentioning

confidence: 99%

Central Circadian Clock Regulates Energy Metabolism

Ding¹,

Gong²,

Eckel‐Mahan³

et al. 2018

Advances in Experimental Medicine and Biology

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“…There are various animal models to mimic human shift work, including altering the timing of food intake, activity, sleep, or light exposure . Disruption of the light‐dark cycle has been shown to disrupt metabolic processes and have profound effects on mammalian physiology, however, the effect of a disrupted light‐dark cycle on gastric vagal afferent satiety signaling remains to be determined.…”

Section: Introductionmentioning

confidence: 99%

Disruption of the light cycle ablates diurnal rhythms in gastric vagal afferent mechanosensitivity

Kentish

Christie

Vincent

et al. 2019

Neurogastroenterology Motil

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Background Gastric vagal afferents (GVAs) respond to mechanical stimulation, initiating satiety. These afferents exhibit diurnal fluctuations in mechanosensitivity, facilitating food intake during the dark phase in rodents. In humans, desynchrony of diurnal rhythms (eg, shift work) is associated with a higher risk of obesity. To test the hypothesis that shift work disrupts satiety signaling, the effect of a rotating light cycles on diurnal rhythms in GVA mechanosensitivity in lean and high‐fat diet (HDF)‐induced obese mice was determined. Methods Male C57BL/6 mice were fed standard laboratory diet (SLD) or HFD for 12 weeks. After 4 weeks, mice were randomly allocated to a normal light (NL; 12 hour light: 12 hour dark; lights on at zeitgeber time [ZT] 0) or rotating light (RL; 3‐day NL cycle, 4‐day reversed light cycle [lights on: ZT12] repeated) cycle for 8 weeks. At week 12, eight mice from each group were housed in metabolic cages. After 12 weeks, ex vivo GVA recordings were taken at 3 hour intervals starting at ZT0. Key Results SLD‐RL and HFD‐RL gained more weight compared to SLD‐NL and HFD‐NL mice, respectively. Gonadal fat pad mass was higher in SLD‐RL compared to SLD‐NL mice. In SLD‐NL mice, tension and mucosal receptor mechanosensitivity exhibited diurnal rhythms with a peak at ZT9. These rhythms were lost in SLD‐RL, HFD‐NL, and HFD‐RL mice and associated with dampened diurnal rhythms in food intake. Conclusions & Inferences GVA diurnal rhythms are susceptible to disturbances in the light cycle and/or the obese state. This may underpin the observed changes in feeding behavior.

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“…Other studies in animals report inconsistent results regarding food intake during day- and night-shift work. A review of animal models of shift work and effects on metabolism found that effects depended on the species examined (rat or mouse) and the protocol used (manipulate timing of activity, light, food intake, and/or sleep) [21]. In human night workers, a recent meta-analysis reported no change in total calorie intake [26], although there are many other documented changes, such as timing of food intake, number, size, and nutritional content of meals [27].…”

Section: Discussionmentioning

confidence: 99%

“…Although several animal models indicate marked metabolic changes due to rest-work [21], only models involving relatively extreme rest-work schedules have been applied so far. The early metabolic effects of simulated night-shift work have yet to be investigated in animal models.…”

Section: Introductionmentioning

confidence: 99%

Shift in Food Intake and Changes in Metabolic Regulation and Gene Expression during Simulated Night-Shift Work: A Rat Model

et al. 2016

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Night-shift work is linked to a shift in food intake toward the normal sleeping period, and to metabolic disturbance. We applied a rat model of night-shift work to assess the immediate effects of such a shift in food intake on metabolism. Male Wistar rats were subjected to 8 h of forced activity during their rest (ZT2-10) or active (ZT14-22) phase. Food intake, body weight, and body temperature were monitored across four work days and eight recovery days. Food intake gradually shifted toward rest-work hours, stabilizing on work day three. A subgroup of animals was euthanized after the third work session for analysis of metabolic gene expression in the liver by real-time polymerase chain reaction (PCR). Results show that work in the rest phase shifted food intake to rest-work hours. Moreover, liver genes related to energy storage and insulin metabolism were upregulated, and genes related to energy breakdown were downregulated compared to non-working time-matched controls. Both working groups lost weight during the protocol and regained weight during recovery, but animals that worked in the rest phase did not fully recover, even after eight days of recovery. In conclusion, three to four days of work in the rest phase is sufficient to induce disruption of several metabolic parameters, which requires more than eight days for full recovery.

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Rodent models to study the metabolic effects of shiftwork in humans

Cited by 73 publications

References 94 publications

Central Circadian Clock Regulates Energy Metabolism

Central Circadian Clock Regulates Energy Metabolism

Disruption of the light cycle ablates diurnal rhythms in gastric vagal afferent mechanosensitivity

Shift in Food Intake and Changes in Metabolic Regulation and Gene Expression during Simulated Night-Shift Work: A Rat Model

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