Shift Work or Food Intake during the Rest Phase Promotes Metabolic Disruption and Desynchrony of Liver Genes in Male Rats

Salgado‐Delgado, Roberto; Saderi, Nadia; Basualdo, María del Carmen; Guerrero‐Vargas, Natalí N.; Escobar, Carolina; Buijs, Ruud M.

doi:10.1371/journal.pone.0060052

Cited by 137 publications

(149 citation statements)

References 47 publications

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“…An endogenous circadian rhythm in circulating glucose and insulin levels has been detected in humans by using intensive protocols performed under constant conditions ("constant routine" protocols) or when the behavioral cycle influences are accounted for by evenly distributing them across the entire circadian cycle ("forced desynchrony" protocols) (4,(10)(11)(12)14). In addition, circadian misalignment-as occurs in shift workers-also leads to impaired glucose metabolism in rodents and humans (10,(25)(26)(27)(28)(29)(30)(31)(32).…”

Section: Significancementioning

confidence: 99%

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Morris

Yang

Garcia

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

364

336

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Glucose tolerance is lower in the evening and at night than in the morning. However, the relative contribution of the circadian system vs. the behavioral cycle (including the sleep/wake and fasting/ feeding cycles) is unclear. Furthermore, although shift work is a diabetes risk factor, the separate impact on glucose tolerance of the behavioral cycle, circadian phase, and circadian disruption (i.e., misalignment between the central circadian pacemaker and the behavioral cycle) has not been systematically studied. Here we show-by using two 8-d laboratory protocols-in healthy adults that the circadian system and circadian misalignment have distinct influences on glucose tolerance, both separate from the behavioral cycle. First, postprandial glucose was 17% higher (i.e., lower glucose tolerance) in the biological evening (8:00 PM) than morning (8:00 AM; i.e., a circadian phase effect), independent of the behavioral cycle effect. Second, circadian misalignment itself (12-h behavioral cycle inversion) increased postprandial glucose by 6%. Third, these variations in glucose tolerance appeared to be explained, at least in part, by different mechanisms: during the biological evening by decreased pancreatic β-cell function (27% lower earlyphase insulin) and during circadian misalignment presumably by decreased insulin sensitivity (elevated postprandial glucose despite 14% higher late-phase insulin) without change in early-phase insulin. We explored possible contributing factors, including changes in polysomnographic sleep and 24-h hormonal profiles. We demonstrate that the circadian system importantly contributes to the reduced glucose tolerance observed in the evening compared with the morning. Separately, circadian misalignment reduces glucose tolerance, providing a mechanism to help explain the increased diabetes risk in shift workers.circadian disruption | shift work | night work | glucose metabolism | diabetes I n healthy humans, there is a strong time-of-day variation in glucose tolerance, with a peak in the morning and a trough in the evening and night (1-6). Understanding the underlying mechanisms of the day/night variation in glucose tolerance is important for diurnally active individuals as well as shift workers, who are at increased risk for developing type 2 diabetes (7-9). The endogenous circadian system and circadian misalignment (i.e., misalignment between the endogenous circadian system and 24-h environmental/behavioral cycles) have been shown to affect glucose metabolism (4,(10)(11)(12)(13)(14). However, the relative and separate importance of the endogenous circadian system and circadian misalignment-after accounting for behavioral cycle effects (including the sleep/wake, fasting/feeding, and physical inactivity/activity cycles, etc.)-on 24-h variation in glucose tolerance is not well understood.Most species have evolved an endogenous circadian timing system that optimally times physiological variations and behaviors relative to the 24-h environmental cycle (15-17). The mammalian circadian system is comp...

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Section: Significancementioning

confidence: 99%

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Morris

Yang

Garcia

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

364

336

View full text Add to dashboard Cite

show abstract

“…74 Forced activity during an 8-hour window of the inactive phase increases body mass, flattens glucose rhythms, alters glucose tolerance, shifts the peak in serum triglycerides to the daytime, and overall alters rhythmicity in the hypothalamus and the liver. [75][76][77] Nighttime food restriction in rats exposed to this forced activity protocol restores glucose rhythms and baseline body mass. 75 Approximately 20% of the global population works in night shifts, forcing individuals to be physically, mentally, and metabolically active out of circadian phase.…”

Section: Circadian Desynchronymentioning

confidence: 90%

“…Restriction of feeding to the inactive phase, during the light phase in nocturnal rodents, increases body mass, fat mass, and liver clock gene profile. 75,76,94 When compounded with a high-fat diet, mice develop obesity, altered circadian endocrine, and locomotor profiles. 60,[95][96][97] Restricting high-fat diet consumption to the active phase, in contrast, can protect against reduced clock gene amplitude, weight gain, and metabolic disease.…”

Section: Delayed Feedingmentioning

confidence: 99%

Consequences of circadian dysregulation on metabolism

Cissé¹,

Nelson²

2016

CPT

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Most organisms display endogenously produced rhythms in physiology and behavior of ~24 hours in duration. These rhythms, termed circadian rhythms, are entrained to precisely 24 hours by the daily extrinsic light-dark cycle. Circadian rhythms are driven by a transcriptional-translational feedback loop that is hierarchically expressed throughout the brain and body; the suprachiasmatic nucleus of the hypothalamus is the master circadian oscillator at the top of the hierarchy. Precise timing of the circadian clocks is critical for many homeostatic processes, including energy regulation and metabolism. Many genes involved in metabolism display rhythmic oscillations. Because circadian rhythms are most potently synchronized with the external environment by light, exposure to light at night potentially disrupts circadian regulation. Other potential disruptors of circadian organization include night shift work, social jet lag, restricted sleep, and misaligned feeding. Each of these environmental conditions has been associated with metabolic changes and obesity. The goal of this review is to highlight how disruption of circadian organization, primarily due to night shift work and exposure to light at night, has downstream effects on metabolic function.

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“…Animal studies 6,8,54,130,131,16,132,133,134,135 6,48,49,50,7,52,8,53,54,55,56,57,58,59,60,5,130,133,135,136,137,138 Human experimental studies x 94,139,140,141,142,143,128 To study the effect of environmental conditions on the circadian clock and peripheral parameters, the animals have been exposed to constant light, dim light at night, aberrant light cycles or shift-work paradigms. The human studies referred to in this .…”

Section: Scn Peripheralmentioning

confidence: 99%

Plasticity of circadian clocks and consequences for metabolism

Coomans

Lucassen

Kooijman

et al. 2015

Diabetes Obesity Metabolism

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The increased prevalence of metabolic disorders and obesity in modern society, together with the widespread use of artificial light at night, have led researchers to investigate whether altered patterns of light exposure contribute to metabolic disorders. This article discusses the experimental evidence that perturbed environmental cycles induce rhythm disorders in the circadian system, thus leading to metabolic disorders. This notion is generally supported by animal studies. Distorted environmental cycles, including continuous exposure to light, affect the neuronal organization of the central circadian pacemaker in the suprachiasmatic nucleus (SCN), its waveform and amplitude of the rhythm in electrical activity. Moreover, repeated exposure to a shifted light cycle or the application of dim light at night are environmental cues that cause a change in SCN function. The effects on the SCN waveform are the result of changes in synchronization among the SCN's neuronal cell population, which lead consistently to metabolic disturbances. Furthermore, we discuss the effects of sleep deprivation and the time of feeding on metabolism, as these factors are associated with exposure to disturbed environmental cycles. Finally, we suggest that these experimental studies reveal a causal relationship between the rhythm disorders and the metabolic disorders observed in epidemiological studies performed in humans. Keywords: circadian, desynchronization, suprachiasmatic nucleus, metabolic disorders, light Date submitted 11 April 2015; date of final acceptance 17 May 2015 Environmental Effects on the Rhythm of the SCNPerturbations in the circadian rhythm can develop under a variety of conditions, including ageing, neurodegenerative diseases and metabolic disorders. In order to effectively treat these diseases, it is important to elucidate the causal relationships behind these associations. Towards that end, several animal models have been used to specifically address the relationship between circadian disorders and metabolic disturbances. These models include transgenic mouse models with specific mutations in clock genes, as well as animals in which the function of the suprachiasmatic nucleus (SCN) has been altered by manipulating environmental cues. Transgenic models have been particularly valuable for elucidating the signalling pathways involved in the pathogenesis of metabolic disorders such as diabetes and obesity [1]. Moreover, performing complementary studies in wild-type animals and studying the effect of the environment on SCN functions are valuable as well, given the growing body of evidence suggesting that improper circadian timing interferes with health. For example, sleep disruption in humans is correlated with an increased risk of developing diabetes, and shift work has been associated with increased body mass index (BMI), altered plasma lipids and impaired insulin sensitivity [2][3][4] (Table 1). These studies indicate a potentially large influence of stable, robust environmental light-dark cycles on the maintenance o...

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Shift Work or Food Intake during the Rest Phase Promotes Metabolic Disruption and Desynchrony of Liver Genes in Male Rats

Cited by 137 publications

References 47 publications

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Consequences of circadian dysregulation on metabolism

Plasticity of circadian clocks and consequences for metabolism

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