Maternal Chronodisruption Throughout Pregnancy Impairs Glucose Homeostasis and Adipose Tissue Physiology in the Male Rat Offspring.

Compelling evidence in rats support the idea that gestational chronodisruption induces major changes in maternal circadian rhythms and fetal development and that these changes impact adult life at many physiological levels. Using a model of chronic photoperiod shifting throughout gestation (CPS), in which pregnant female rats (Sprague-Dawley strain; n = 16 per group) were exposed to lighting schedule manipulation every 3-4 days reversing the photoperiod completely or light/dark photoperiod (12/12; LD), we explored in the adult rat male offspring body weight gain, glucose homeostasis, adipose tissue content, adipose tissue response to norepinephrine (NE), and adipose tissue proteomic in the basal condition with standard diet (SD) and in response to high-fat diet (HFD). In adult CPS male (100-200 days old; n = 8 per group), we found increasing body weight, under SD and adiposity. Also, we found an increased response to intraperitoneal glucose (IGTT). After 12 weeks of HFD, white adipose tissue depots in CPS offspring were increased further, and higher IGTT and lower intraperitoneal insulin tolerance response were found, despite the lack of changes in food intake. In in vitro experiments, we observed that adipose tissue (WAT and BAT) glycerol response to NE from CPS offspring was decreased, and it was completely abolished by HFD. At the proteomic level, in CPS adipose tissue, 275 proteins displayed differential expression, compared with LD animals fed with a standard diet. Interestingly, CPS offspring and LD fed with HFD showed 20 proteins in common (2 upregulated and 18 downregulated). Based on these common proteins, the IPA analysis found that two functional pathways were significantly altered by CPS: network 1 (AKT/ERK) and network 2 (TNF/IL4; data are available via ProteomeXchange with identifier PXD026315). The present data show that gestational chronodisruption induced deleterious effects in adipose tissue recruitment and function, supporting the idea that adipose tissue function was programmed in utero by gestational chronodisruption, inducing deficient metabolic responses that persist into adulthood.

The Period 2 Enhancer Nobiletin as Novel Therapy in Murine Models of Circadian Disruption Resembling Delirium.

OBJECTIVES: Delirium occurs in approximately 30% of critically ill patients, and the risk of dying during admission doubles in those patients. Molecular mechanisms causing delirium are largely unknown. However, critical illness and the ICU environment consistently disrupt circadian rhythms, and circadian disruptions are strongly associated with delirium. Exposure to benzodiazepines and constant light are suspected risk factors for the development of delirium. Thus, we tested the functional role of the circadian rhythm protein Period 2 (PER2) in different mouse models resembling delirium. DESIGN: Animal study. SETTING: University experimental laboratory. SUBJECTS: Wildtype, Per2 mice. INTERVENTIONS: Midazolam, lipopolysaccharide (lipopolysaccharide), constant light, nobiletin, or sham-treated animals. MEASUREMENTS AND MAIN RESULTS: Midazolam significantly reduced the expression of PER2 in the suprachiasmatic nucleus and the hippocampus of wild-type mice. Behavioral tests following midazolam exposure revealed a robust phenotype including executive dysfunction and memory impairment suggestive of delirium. These findings indicated a critical role of hippocampal expressed PER2. Similar results were obtained in mice exposed to lipopolysaccharide or constant light. Subsequent studies in Per2 mice confirmed a functional role of PER2 in a midazolam-induced delirium-like phenotype. Using the small molecule nobiletin to enhance PER2 function, the cognitive deficits induced by midazolam or constant light were attenuated in wild-type mice. CONCLUSIONS: These experiments identify a novel role for PER2 during a midazolam- or constant light-induced delirium-like state, highlight the importance of hippocampal PER2 expression for cognitive function, and suggest the PER2 enhancer nobiletin as potential therapy in delirium-like conditions associated with circadian disruption.

[Alteration of biological rhythms causes metabolic diseases and obesity]. / La alteracion de los ritmos biologicos causa enfermedades metabolicas y obesidad.

The incidence of obesity worldwide has become a serious, constantly growing public health issue that reaches alarming proportions in some countries. To date none of the strategies developed to combat obesity have proved to be decisive, and hence there is an urgent need to address the problem with new approaches. Today, studies in the field of chronobiology have shown that our physiology continually adapts itself to the cyclical changes in the environment, regard-less of whether they are daily or seasonal. This is possible thanks to the existence of a biological clock in our hypothalamus which regulates the expression and/or activity of enzymes and hormones involved in regulating our metabolism, as well as all the homeostatic functions. It has been observed that this clock can be upset as a result of today's modern lifestyle, which involves a drop in physical activity during the day and the abundant ingestion of food during the night, among other factors, which together promote metabolic syndrome and obesity. Hence, the aim of this review is to summarise the recent findings that show the effect that altering the circadian rhythms has on the metabolism and how this can play a part in the development of metabolic diseases.

TITLE: La alteracion de los ritmos biologicos causa enfermedades metabolicas y obesidad.La incidencia de la obesidad a escala mundial se ha convertido en un grave y creciente problema de salud publica, que alcanza en algunos paises proporciones alarmantes, y hasta el momento ninguna de las estrategias desarrolladas para combatir la obesidad se ha demostrado resolutiva, por lo que es urgente abordar el problema con nuevos enfoques. Actualmente, en el estudio de la cronobiologia se ha demostrado que nuestra fisiologia se adapta continuamente a los cambios ciclicos del ambiente, sean estos diarios o estacionales, debido a la presencia de un reloj biologico en nuestro hipotalamo que regula la expresion y actividad de enzimas y hormonas implicadas en la regulacion del metabolismo, asi como de todas las funciones homeostaticas. Se ha observado que este reloj puede alterarse debido al estilo de vida moderno, que implica una baja actividad fisica durante el dia e ingesta abundante de comida durante la noche, entre otros factores, que promueven todos ellos el sindrome metabolico y la obesidad. Por lo tanto, el objetivo de esta revision es resumir los hallazgos recientes que demuestran el efecto de la alteracion circadiana sobre el metabolismo y como esta puede participar en el desarrollo de enfermedades metabolicas.

Metabolic impact of shift work.

In developing countries, shift work represents a considerable contingent workforce. Recently, studies have shown that overweight and obesity are more prevalent in shift workers than day workers. In addition, shift work has been associated with a higher propensity for the development of many metabolic disorders, such as insulin resistance, diabetes, dislipidemias and metabolic syndrome. Recent data have pointed that decrease of the sleep time, desynchronization of circadian rhythm and alteration of environmental aspects are the main factors related to such problems. Shortened or disturbed sleep is among the most common health-related effects of shift work. The plausible physiological and biological mechanisms are related to the activation of the autonomic nervous system, inflammation, changes in lipid and glucose metabolism, and related changes in the risk for atherosclerosis, metabolic syndrome, and type II diabetes. The present review will discuss the impact of shift work on obesity and metabolic disorders and how disruption of sleep and circadian misalignment may contribute to these metabolic dysfunctions.

Circadian disorganization in experimental arthritis.

This review discusses the experimental evidence indicating that arthritis disrupts circadian organization, which was mainly derived from animal studies employing Freund's complete mycobacterial adjuvant (FCA). The defense response to antigenic challenge, mediated in part by cytokines, includes changes in chronobiological central nervous system function, like depressed daily activity, superficial sleep or anorexia. Interferon (IFN)-gamma receptors are detectable in the central circadian pacemaker, the hypothalamic suprachiasmatic nuclei, at a time when the capacity for photic entrainment of the pacemaker became established. The disruptive effects of the systemic injection of IFN on the circadian rhythms of locomotor activity, body temperature and clock-gene mRNA expression have been documented. In the last few years we have examined a number of immune and neuroendocrine circadian rhythms in FCA-injected rats, both in the preclinical phase of arthritis (2-3 days after FCA injection) as well as in the acute phase of the disease (18 days after FCA injection). In arthritic rats, the 24-hour organization of immune and neuroendocrine responses becomes altered. A hormonal pathway involving the circadian secretion of melatonin and a purely neural pathway including, as a motor leg, the autonomic nervous system innervating the lymph nodes were identified. The significant effects of the immune-mediated inflammatory response on the diurnal rhythmicity of adenohypophysial and hypophysiotropic hormones occurred in arthritic rats. Melatonin treatment prevented the alteration in 24-hour rhythms of serum ACTH, prolactin and luteinizing hormone in rats injected with FCA. In addition, melatonin pretreatment prevented the alteration in the 24-hour variation in hypothalamic serotonin and dopamine turnover during the preclinical phase of Freund's adjuvant arthritis in rats. Some pinealectomy-induced immune changes in arthritic rats were also prevented by physiological concentrations of melatonin. Melatonin may play the role of an 'internal synchronizer' for the immune system.

Hypothalamic involvement in chronic migraine.

OBJECTIVES: Chronic migraine (CM), previously called transformed migraine, is a frequent headache disorder that affects 2%-3% of the general population. Analgesic overuse, insomnia, depression, and anxiety are disorders that are often comorbid with CM. Hypothalamic dysfunction has been implicated in its pathogenesis, but it has never been studied in patients with CM. The aim was to analyze hypothalamic involvement in CM by measurement of melatonin, prolactin, growth hormone, and cortisol nocturnal secretion. METHODS: A total of 338 blood samples (13/patient) from 17 patients with CM and nine age and sex matched healthy volunteers were taken. Melatonin, prolactin, growth hormone, and cortisol concentrations were determined every hour for 12 hours. The presence of comorbid disorders was also evaluated. RESULTS: An abnormal pattern of hypothalamic hormonal secretion was found in CM. This included: (1) a decreased nocturnal prolactin peak, (2) increased cortisol concentrations, (3) a delayed nocturnal melatonin peak in patients with CM, and (4) lower melatonin concentrations in patients with CM with insomnia. Growth hormone secretion did not differ from controls. CONCLUSION: These results support hypothalamic involvement in CM, shown by a chronobiologic dysregulation, and a possible hyperdopaminergic state in patients with CM. Insomnia might be an important variable in the study findings.