Orexin activation precedes increased NPY expression, hyperphagia, and metabolic changes in response to sleep deprivation

2010 ◽  
Vol 298 (3) ◽  
pp. E726-E734 ◽  
Author(s):  
Paulo José Forcina Martins ◽  
Marina Soares Marques ◽  
Sergio Tufik ◽  
Vânia D'Almeida
Keyword(s):  
Body Weight ◽  
Energy Balance ◽  
Food Intake ◽  
Sleep Deprivation ◽  
Weight Control ◽  
Time Course ◽  
Energy Homeostasis ◽  
Negative Energy ◽  
Negative Energy Balance ◽  
Mrna Levels

Several pieces of evidence support that sleep duration plays a role in body weight control. Nevertheless, it has been assumed that, after the identification of orexins (hypocretins), the molecular basis of the interaction between sleep and energy homeostasis has been provided. However, no study has verified the relationship between neuropeptide Y (NPY) and orexin changes during hyperphagia induced by sleep deprivation. In the current study we aimed to establish the time course of changes in metabolite, endocrine, and hypothalamic neuropeptide expression of Wistar rats sleep deprived by the platform method for a distinct period (from 24 to 96 h) or sleep restricted for 21 days (SR-21d). Despite changes in the stress hormones, we found no changes in food intake and body weight in the SR-21d group. However, sleep-deprived rats had a 25–35% increase in their food intake from 72 h accompanied by slight weight loss. Such changes were associated with increased hypothalamus mRNA levels of prepro-orexin (PPO) at 24 h followed by NPY at 48 h of sleep deprivation. Conversely, sleep recovery reduced the expression of both PPO and NPY, which rapidly brought the animals to a hypophagic condition. Our data also support that sleep deprivation rapidly increases energy expenditure and therefore leads to a negative energy balance and a reduction in liver glycogen and serum triacylglycerol levels despite the hyperphagia. Interestingly, such changes were associated with increased serum levels of glucagon, corticosterone, and norepinephrine, but no effects on leptin, insulin, or ghrelin were observed. In conclusion, orexin activation accounts for the myriad changes induced by sleep deprivation, especially the hyperphagia induced under stress and a negative energy balance.

Hypothalamic regulation of energy homeostasis when consuming diets of different energy concentrations: Comparison between Tibetan and Small-tailed Han sheep

2021 ◽  
pp. 1-25
Author(s):  
Xiaoping Jing ◽  
Yamin Guo ◽  
Allan Degen ◽  
Wenji Wang ◽  
Jingpeng Kang ◽  
...  
Keyword(s):  
Body Weight ◽  
Energy Balance ◽  
Energy Intake ◽  
Energy Homeostasis ◽  
Negative Energy ◽  
Negative Energy Balance ◽  
Positive Energy ◽  
Tibetan Sheep ◽  
Protein Expressions ◽  
Positive Energy Balance

Abstract Seasonal energy intake of Tibetan sheep on the harsh Qinghai-Tibetan Plateau (QTP) fluctuates greatly and is often well below maintenance requirements. The aim of this study was to gain insight into how the hypothalamus regulates energy homeostasis in Tibetan and Small-tailed Han sheep. We compared Tibetan and Small-tailed Han sheep (n=24 of each breed), which were offered one of four diets that differed in digestible energy (DE) densities: 8.21, 9.33, 10.45 and 11.57 MJ/kg dry matter. Sheep were weighed every two weeks, and it was assumed that the change in body weight reflected the change in energy balance. The arcuate nucleus of the hypothalamus in Tibetan sheep had greater protein expressions of neuropeptide Y (NPY) and agouti-related peptide (AgRP) when in negative energy balance, but lesser protein expressions of proopiomelanocortin (POMC) and cocaine and amphetamine-regulated transcript (CART) when in positive energy balance than Small-tailed Han sheep. As a result, Tibetan sheep had a lesser body weight (BW) loss when in negative energy balance and stored more energy and gained more BW when in positive energy balance than Small-tailed Han sheep with the same dietary intake. Moreover, in the hypothalamic AMPK regulation pathway, Tibetan sheep had greater AMPKα2 protein expression than Small-tailed Han sheep, which supported the premise of a better ability to regulate energy homeostasis and better growth performance. These differences in the hypothalamic NPY/AgRP, POMC/CART and AMPK pathways between breeds conferred an advantage to the Tibetan over Small-tailed Han sheep to cope with low energy intake on the harsh QTP.

Secretin as a satiation whisperer with the potential to turn into an obesity-curbing knight

Endocrinology ◽  
2021 ◽  
Author(s):  
Katharina Schnabl ◽  
Yongguo Li ◽  
Mueez U-Din ◽  
Martin Klingenspor
Keyword(s):  
Bariatric Surgery ◽  
Body Weight ◽  
Energy Balance ◽  
Food Intake ◽  
Weight Control ◽  
Therapeutic Potential ◽  
Physiological Mechanism ◽  
Gut Hormones ◽  
Metabolic Effects ◽  
Beneficial Effects

Abstract The obesity pandemic requires effective preventative and therapeutic intervention strategies. Successful and sustained obesity treatment is currently limited to bariatric surgery. Modulating the release of gut hormones is considered promising to mimic bariatric surgery with its beneficial effects on food intake, body weight and blood glucose levels. The gut peptide secretin was the first molecule to be termed a hormone; nevertheless, it only recently has been established as a legitimate anorexigenic peptide. In contrast to gut hormones that crosstalk with the brain either directly or by afferent neuronal projections, secretin mediates meal-associated brown fat thermogenesis to induce meal termination, thereby qualifying this physiological mechanism as an attractive, peripheral target for the treatment of obesity. In this perspective, it is of pivotal interest to deepen our yet superficial knowledge on the physiological roles of secretin as well as meal-associated thermogenesis in energy balance and body weight regulation. Of note, the emerging differences between meal-associated thermogenesis and cold-induced thermogenesis must be taken into account. In fact, there is no correlation between these two entities. In addition, the investigation of potential effects of secretin in hedonic-driven food intake, bariatric surgery as well as chronic treatment using suitable application strategies to overcome pharmacokinetic limitations will provide further insight into its potential to influence energy balance. The aim of this article is to review the facts on secretin’s metabolic effects, address prevailing gaps in our knowledge, and provide an overview on the opportunities and challenges of the therapeutic potential of secretin in body weight control.

Session 2: Calorie-Cutting Keys

2016 ◽  
pp. 15-26
Author(s):  
Evan M. Forman ◽  
Meghan L. Butryn
Keyword(s):  
Energy Balance ◽  
Food Intake ◽  
Eating Behavior ◽  
Negative Energy ◽  
Negative Energy Balance ◽  
Calorie Intake ◽  
Self Monitoring ◽  
Serving Size ◽  
High Calorie

This chapter (Session 2) discusses the importance of self-monitoring to gain awareness of calorie intake and to recognize patterns in eating behavior. Clients are provided with information on how to self-monitor food intake, including recording type of food, serving size, method of preparation, and time of eating. Strategies for beginning to reduce calories are discussed, such as limiting high-calorie foods in the environment, eating regular meals, and planning meals in advance. The idea of achieving a negative energy balance is introduced, meaning that in order to lose weight, clients must expend a greater amount of energy than they consume in the form of calories.

scholarly journals Metabolic adaptations during negative energy balance and their potential impact on appetite and food intake

2019 ◽  
Vol 78 (3) ◽  
pp. 279-289 ◽  
Author(s):  
Nuno Casanova ◽  
Kristine Beaulieu ◽  
Graham Finlayson ◽  
Mark Hopkins
Keyword(s):  
Weight Loss ◽  
Energy Balance ◽  
Food Intake ◽  
Negative Energy ◽  
Fat Free Mass ◽  
Negative Energy Balance ◽  
Energy Deficit ◽  
Behavioural Responses ◽  
Compensatory Responses ◽  
Metabolic Adaptations

This review examines the metabolic adaptations that occur in response to negative energy balance and their potential putative or functional impact on appetite and food intake. Sustained negative energy balance will result in weight loss, with body composition changes similar for different dietary interventions if total energy and protein intake are equated. During periods of underfeeding, compensatory metabolic and behavioural responses occur that attenuate the prescribed energy deficit. While losses of metabolically active tissue during energy deficit result in reduced energy expenditure, an additional down-regulation in expenditure has been noted that cannot be explained by changes in body tissue (e.g. adaptive thermogenesis). Sustained negative energy balance is also associated with an increase in orexigenic drive and changes in appetite-related peptides during weight loss that may act as cues for increased hunger and food intake. It has also been suggested that losses of fat-free mass (FFM) could also act as an orexigenic signal during weight loss, but more data are needed to support these findings and the signalling pathways linking FFM and energy intake remain unclear. Taken together, these metabolic and behavioural responses to weight loss point to a highly complex and dynamic energy balance system in which perturbations to individual components can cause co-ordinated and inter-related compensatory responses elsewhere. The strength of these compensatory responses is individually subtle, and early identification of this variability may help identify individuals that respond well or poorly to an intervention.

scholarly journals The Effect of a 2-Week Red Ginseng Supplementation on Food Efficiency and Energy Metabolism in Mice

Nutrients ◽  
2020 ◽  
Vol 12 (6) ◽  
pp. 1726
Author(s):  
Hyejung Hwang ◽  
Jisu Kim ◽  
Kiwon Lim
Keyword(s):  
Body Weight ◽  
Energy Metabolism ◽  
Food Intake ◽  
Weight Control ◽  
Fat Oxidation ◽  
Substrate Utilization ◽  
Mrna Levels ◽  
Red Ginseng ◽  
Energy Substrate ◽  
Metabolism Regulation

Red ginseng (RG) ingestion reportedly affects body weight, food intake, and fat accumulation reduction. It also induces changes in energy metabolism regulation and glycemic control. Previously, 2-week RG ingestion with endurance training was found to enhance fat oxidation during exercise. However, such effects on energy metabolism and the expression of mRNAs related to energy substrate utilization in resting mice (untrained mice) are still unclear. Here, we determined the effect of RG on energy metabolism and substrate utilization in untrained male mice. Twenty-four mice were separated into an RG group that received a daily dosage of 1 g/kg RG for 2 weeks, and a control (CON). Energy expenditure, blood and tissue glycogen levels, and expression of mRNAs related to energy substrate utilization in muscles were measured before and 2 weeks after treatment. Total food intake was significantly lower in the RG than in the CON group (p < 0.05), but final body weights did not differ. Carbohydrate and fat oxidation over 24 h did not change in either group. There were no significant differences in gastrocnemius GLUT4, MCT1, MCT4, FAT/CD36, and CPT1b mRNA levels between groups. Thus, the effects of RG ingested during rest differ from the effects of RG ingestion in combination with endurance exercise; administering RG to untrained mice for 2 weeks did not change body weight and energy metabolism. Therefore, future studies should consider examining the RG ingestion period and dosage for body weight control and improving energy metabolism.

scholarly journals Regulation of serum leptin and its role in the hyperphagia of lactation in the rat

2003 ◽  
Vol 176 (2) ◽  
pp. 193-203 ◽  
Author(s):  
RG Denis ◽  
G Williams ◽  
RG Vernon
Keyword(s):  
Energy Balance ◽  
Food Intake ◽  
Milk Production ◽  
Litter Size ◽  
High Energy ◽  
Negative Energy ◽  
Negative Energy Balance ◽  
Calorie Intake ◽  
Serum Leptin ◽  
Nocturnal Rise

The factors regulating serum leptin concentration and its relationship to the hyperphagia of lactation have been investigated in rats. Lactation results in hypoleptinaemia and loss, or at least marked attenuation, of the nocturnal rise in serum leptin. Litter removal resulted in a fall in food intake and restoration of the nocturnal rise in serum leptin. Returning the litter to the mother after a 48-h absence increased food intake and began to reinitiate milk production, but the nocturnal serum leptin levels were still increased at 48 h after litter restoration. Adjusting litter size to four, eight, ten or fourteen pups at parturition resulted in different rates of litter growth and food intake during the subsequent lactation, but had no effect on the degree of hypoleptinaemia. Reducing litter size from ten to four pups at mid-lactation resulted in a transient increase in both serum leptin and pup growth rate, while food intake fell to a level found in rats suckling four pups throughout lactation. Reducing milk production by injection of bromocriptine increased serum leptin, but did not restore the nocturnal rise in serum leptin; food intake decreased, but remained much higher than in non-lactating rats. Feeding a varied, high-energy diet resulted in a decrease in the weight of food ingested, but no change in calorie intake, and had no effect on the hypoleptinaemia. These studies suggested that the hypoleptinaemia of lactating rats is due to negative energy balance, but the loss of the nocturnal rise in serum leptin is due to the suckling stimulus. The negative energy balance of lactation does not appear to be caused by a physical constraint on food intake. While the hypoleptinaemia should facilitate the hyperphagia of lactation, other orexigenic signals must also be involved.

Relationships between energy balance and health traits of dairy cattle in early lactation

1999 ◽  
Vol 24 ◽  
pp. 171-175 ◽  
Author(s):  
B. L. Collard ◽  
P. J. Boettcher ◽  
J. C. M. Dekkers ◽  
L. R. Schaeffer ◽  
D. Petitclerc
Keyword(s):  
Energy Balance ◽  
Food Intake ◽  
Total Energy ◽  
Milk Production ◽  
Additive Genetic Variance ◽  
Negative Energy ◽  
Negative Energy Balance ◽  
Energy Deficit ◽  
Research Station ◽  
Daily Energy

AbstractData were records of daily food intake and milk production, periodic measures of milk composition and all health and reproductive information from 140 multiparous Holstein cows involved in various experiments at the Agriculture Canada dairy research station in Lennoxville, Quebec. Energy concentrations of the total mixed rations were also available. Daily energy balance was calculated by multiplying the food intake by the concentration of energy in the diet and then subtracting from this quantity the expected (National Research Council) amount of energy required for maintenance (based on parity and body weight) and for milk production (based on yield and concentrations of fat, protein and lactose). Four energy balance traits were defined: (1) average daily energy balance within the first 10 to 100 days of lactation, (2) minimum daily energy balance, (3) days in negative energy balance and (4) total energy deficit during the period of negative energy balance. Health traits were the numbers of incidences of each of the following: (1) all udder problems, (2) mastitis, (3) all locomotive problems, (4) laminitis, (5) digestive problems and (6) reproductive problems. Reproductive traits were the number of days to first observed oestrous and number of inseminations. Phenotypic relationships between energy balance and health were investigated by regressing the energy balance traits on each health trait. Parity and treatment (according to the research trial that the cow was involved with) were also included in the model. Genetic parameters were estimated with restricted maximum likelihood and a model that included effects of parity, treatment and animal. Phenotypically, several significant (P<0.10) relationships between energy balance and health were observed. Cows with longer periods of negative energy balance had increased digestive problems. Cows with greater total energy deficit had more digestive problems and laminitis. Estimates of heritabilities for energy intake and milk energy were 0.42 and 0.12, respectively but estimates of heritability for all energy balance traits were zero. The low estimates for these traits may have been due to (1) low true additive genetic variance, (2) small amount of data, or (3) relatively few genetic ties among cows.

Effect of intracerebroventricular α-MSH on food intake, adiposity, c-Fos induction, and neuropeptide expression

2000 ◽  
Vol 279 (2) ◽  
pp. R695-R703 ◽  
Author(s):  
Julie E. McMinn ◽  
Charles W. Wilkinson ◽  
Peter J. Havel ◽  
Stephen C. Woods ◽  
Michael W. Schwartz
Keyword(s):  
Body Weight ◽  
Food Intake ◽  
Energy Homeostasis ◽  
Melanocortin Receptor ◽  
Mrna Levels ◽  
Melanocyte Stimulating Hormone ◽  
The Third ◽  
Chronic Infusion ◽  
Plasma Insulin Levels ◽  
Cumulative Food Intake

α-Melanocyte-stimulating hormone (α-MSH) is a hypothalamic neuropeptide proposed to play a key role in energy homeostasis. To investigate the behavioral, metabolic, and hypothalamic responses to chronic central α-MSH administration, α-MSH was infused continuously into the third cerebral ventricle of rats for 6 days. Chronic α-MSH infusion reduced cumulative food intake by 10.7% ( P < 0.05 vs. saline) and body weight by 4.3% ( P < 0.01 vs. saline), which in turn lowered plasma insulin levels by 29.3% ( P < 0.05 vs. saline). However, α-MSH did not cause adipose-specific wasting nor did it alter hypothalamic neuropeptide mRNA levels. Central α-MSH infusion acutely activated neurons in forebrain areas such as the hypothalamic paraventricular nucleus, as measured by a 254% increase in c-Fos-like immunoreactivity ( P < 0.01 vs. saline), as well as satiety pathways in the hindbrain. Our findings suggest that, although an increase of central melanocortin receptor signaling acutely reduces food intake and body weight, its anorectic potency wanes during chronic infusion and causes only a modest decrease of body weight.

scholarly journals Insulin restores GH responsiveness during lactation-induced negative energy balance in dairy cattle: effects on expression of IGF-I and GH receptor 1A

2003 ◽  
Vol 176 (2) ◽  
pp. 205-217 ◽  
Author(s):  
ST Butler ◽  
AL Marr ◽  
SH Pelton ◽  
RP Radcliff ◽  
MC Lucy ◽  
...  
Keyword(s):  
Adipose Tissue ◽  
Blood Glucose ◽  
Energy Balance ◽  
Dairy Cattle ◽  
Negative Energy ◽  
Negative Energy Balance ◽  
Mrna Levels ◽  
Hepatic Expression ◽  
Gh Receptor ◽  
Igf I

Early lactation in dairy cattle is a period of severe negative energy balance (NEB) characterized by reduced blood glucose and insulin concentrations and elevated blood GH concentrations. The liver is refractory to GH during NEB and this uncoupling of the GH-IGF axis results in diminished plasma concentrations of IGF-I. Our objectives were to examine the effects of insulin administration during the immediate postpartum period on plasma IGF-I and GH concentrations and to examine the hepatic expression of total GH receptors (all GH receptor transcripts), GH receptor 1A (GHR 1A) and IGF-I. In addition, we examined adipose tissue for total GH receptor and IGF-I mRNA levels to establish the effects of chronic hyperinsulinemia on an insulin-responsive peripheral tissue. Holstein cows (n=14) were subjected to either a hyperinsulinemic-euglycemic clamp (insulin; INS) or saline infusion (control; CTL) for 96 h starting on day 10 postpartum. Insulin was infused i.v. (1 micro g/kg body weight per h), blood samples were collected hourly, and euglycemia was maintained by infusion of glucose. Insulin concentrations during the infusions were increased 8-fold in INS compared with CTL cows (2.33+/-0.14 vs 0.27+/-0.14 ng/ml (S.E.M.); P<0.001) while blood glucose concentrations were not different between treatments (45.3+/-2.2 vs 42.5+/-2.2 mg/dl; P>0.1). Plasma IGF-I increased continuously during the insulin infusion, and reached the highest concentrations at the end of the clamp, being almost 4-fold higher in INS compared with CTL cows (117+/-4 vs 30+/-4 ng/ml; P<0.001). Hepatic expression of GHR 1A and IGF-I mRNA was low in CTL cows, but was increased 3.6-fold (P<0.05) and 6.3-fold (P<0.001) respectively in INS cows. By contrast, in adipose tissue the changes in gene expression in response to insulin were reversed with decreases in both total GHR and IGF-I mRNA. The expressions of GHR 1A and IGF-I mRNA in liver tissue were correlated in INS (r=0.86; P<0.05), but not CTL cows (r=0.43; P>0.1). Insulin appears to be a key metabolic signal in coupling the GH-IGF axis, thus orchestrating a marked elevation in circulating IGF-I concentrations.

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