A free-choice high-fat high-sugar diet induces changes in arcuate neuropeptide expression that support hyperphagia
Objectives:The mechanisms for how saturated fat and sugar-based beverages contribute to human obesity are poorly understood. This paper describes a series of experiments developed to examine the response of hypothalamic neuropeptides to diets rich in sugar and fat, using three different diets: a high-fat high-sugar (HFHS) choice diet with access to chow, saturated fat and a 30% sugar solution; a high-fat (HF) choice diet with access to chow and saturated fat; or to a high-sugar (HS) choice diet with access to chow and a sugar solution. Method: We first studied caloric intake, body weight gain, hormonal alterations and hypothalamic neuropeptide expression when male Wistar rats were subjected to an HFHS choice, an HF choice or an HS choice diet for 1 week. Next, we studied caloric intake and body weight gain when rats were subjected to the choice diets for 5 weeks. Finally, we measured neuropeptide expression in hepatic vagotomized rats subjected to an HFHS choice, an HF choice or an HS choice diet for 1 week. Results: In rats on an HF choice diet, plasma leptin concentrations and proopiomelanocortin (POMC) mRNA increased and neuropeptide Y (NPY) mRNA decreased. Rats on an HFHS choice diet showed identical plasma leptin concentrations as rats on an HF choice diet. However, NPY mRNA increased and POMC mRNA decreased. An HS choice diet for 1 week did not alter hypothalamic neuropeptide expression or plasma leptin concentrations. As hormonal changes did not explain the differences in hypothalamic neuropeptide expression between rats on the choice diets, we addressed whether neuronal feedback signals mediated the hypothalamic neuropeptide response. The POMC mRNA response to different diets depended on an intact innervation of liver and upper intestinal tract. Conclusion: Our data suggest that the specific combination of saturated fat and a 30% sugar solution results in hyperphagiainduced obesity and alters hypothalamic neuropeptide expression, and that the response of the melanocortin system is mediated by the hepatic vagus.
Objectives: One of the main causes of obesity is overconsumption of diets high in fat and sugar. We studied the metabolic changes and food-motivated behavior when rats were subjected to a choice diet with chow, lard and a 30% sucrose solution (high fat high sugar (HFHS)-choice diet). Because rats showed considerable variations in the feeding response to HFHS-choice diet and in food-motivated behavior, we investigated whether the motivation to obtain a sucrose reward correlated with the development of obesity when rats were subsequently subjected to HFHS-choice diet. Method: We first studied feeding, locomotor activity and body temperature, fat weights and hormonal concentrations when male Wistar rats were subjected to HFHS-choice diet for 1 week. Second, we studied sucrose-motivated behavior, using a progressive ratio (PR) schedule of reinforcement in rats that were subjected to the HFHS-choice diet for at least 2 weeks, compared to control rats on a chow diet. Third, we measured motivation for sucrose under a PR schedule of reinforcement in rats that were subsequently subjected to HFHS-choice diet or a chow diet for 4 weeks. Fat weights were measured and correlated with the motivation to obtain sucrose pellets. Results: One week on the HFHS-choice diet increased plasma concentrations of glucose and leptin, increased fat stores, but did not alter body temperature or locomotor activity. Moreover, consuming the HFHS-choice diet for several weeks increased the motivation to work for sucrose pellets. Furthermore, the motivation to obtain sucrose pellets correlated positively with abdominal fat stores in rats subsequently subjected to the HFHS-choice diet, whereas this correlation was not found in rats fed on a chow diet. Conclusion: Our data suggest that the motivation to respond for palatable food correlates with obesity due to an obesogenic environment. Conversely, the HFHS-choice diet, which results in obesity, also increased the motivation to work for sucrose. Thus, being motivated to work for sucrose results in obesity, which, in turn, increases food-motivated behavior, resulting in a vicious circle of food motivation and obesity. IntroductionObesity is one of the fastest growing medical problems in modern society. It contributes to the development of chronic disorders such as cardiovascular disease, type 2 diabetes, hypertension and some cancers. 1 For healthy body weight regulation, it is important to balance energy intake and energy expenditure. Modern society, however, is characterized by a sedentary lifestyle and a calorie intake, which is not adjusted for that. Although regulatory mechanisms that balance intake and expenditure are known , 2,3 it still remains unclear why this fails in obese individuals. It has been postulated that the ability to overconsume high-energy dense foods (in the face of plentiful food availability) was selected during evolution. Thus, under conditions when food availability is uncertain and scarce, consuming highenergy dense foods is an adequate adaptation (for a review see Uli...
The snacking rat as model of human obesity: effects of a free-choice high-fat high-sugar diet on meal patterns
We hereby show the importance of choice in the observation of fcHFHS diet-induced hyperphagia, which results in increases in meal number due to sugar drinking without any compensatory decrease in meal size. We thus provide a novel dietary model in rats that mimics important features of human overconsumption that have been ignored in rodent models of obesity.
We here describe a technique to transiently activate specific neural pathways in vivo. It comprises the combined use of a CRE-recombinase expressing canine adenovirus-2 (CAV-2) and an adeno-associated virus (AAV-hSyn-DIO-hM3D(Gq)-mCherry) that contains the floxed inverted sequence of the designer receptor exclusively activated by designer drugs (DREADD) hM3D(Gq)-mCherry. CAV-2 retrogradely infects projection neurons, which allowed us to specifically express hM3D(Gq)-mCherry in neurons that project from the ventral tegmental area (VTA) to the nucleus accumbens (Acb), the majority of which were dopaminergic. Activation of hM3D(Gq)-mCherry by intraperitoneal (i.p.) injections of clozapine-N-oxide (CNO) leads to increases in neuronal activity, which enabled us to specifically activate VTA to Acb projection neurons. The VTA to Acb pathway is part of the mesolimbic dopamine system and has been implicated in behavioral activation and the exertion of effort. Injections of all doses of CNO led to increases in progressive ratio (PR) performance. The effect of the lowest dose of CNO was suppressed by administration of a DRD1-antagonist, suggesting that CNO-induced increases in PR-performance are at least in part mediated by DRD1-signaling. We hereby validate the combined use of CAV-2 and DREADD-technology to activate specific neural pathways and determine consequent changes in behaviorally relevant paradigms.
A free-choice high-fat high-sugar diet induces glucose intolerance and insulin unresponsiveness to a glucose load not explained by obesity
Objectives: In diet-induced obesity, it is not clear whether impaired glucose metabolism is caused directly by the diet, or indirectly via obesity. This study examined the effects of different free-choice, high-caloric, obesity-inducing diets on glucose metabolism. In these free-choice diets, saturated fat and/or a 30% sugar solution are provided in an addition to normal chow pellets. Method: In the first experiment, male rats received a free-choice high-fat high-sugar (HFHS), free-choice high-fat (HF) or a chow diet. In a second experiment, male rats received a free-choice high-sugar (HS) diet or chow diet. For both experiments, after weeks 1 and 4, an intravenous glucose tolerance test was performed. Results: Both the HFHS and HF diets resulted in obesity with comparable plasma concentrations of free fatty acids. Interestingly, the HF diet did not affect glucose metabolism, whereas the HFHS diet resulted in hyperglycemia, hyperinsulinemia and in glucose intolerance because of a diminished insulin response. Moreover, adiposity in rats on the HF diet correlated positively with the insulin response to the glucose load, whereas adiposity in rats on the HFHS diet showed a negative correlation. In addition, total caloric intake did not explain differences in glucose tolerance. To test whether sugar itself was crucial, we next performed a similar experiment in rats on the HS diet. Rats consumed three times as much sugar when compared with rats on the HFHS diet, which resulted in obesity with basal hyperinsulinemia. Glucose tolerance, however, was not affected. Conclusion: Together, these results suggest that not only obesity or total caloric intake, but the diet content also is crucial for the glucose intolerance that we observed in rats on the HFHS diet.
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