Consumption of a high-fat diet induces central insulin resistance independent of adiposity

Plasma insulin enters the CNS where it interacts with insulin receptors in areas that are related to energy homeostasis and elicits a decrease of food intake and body weight. Here, we demonstrate that consumption of a high-fat (HF) diet impairs the central actions of insulin. Male Long-Evans rats were given chronic (70-day) or acute (3-day) ad libitum access to HF, low-fat (LF), or chow diets. Insulin administered into the 3rd-cerebral ventricle (i3vt) decreased food intake and body weight of LF and chow rats but had no effect on HF rats in either the chronic or the acute experiment. Rats chronically pair-fed the HF diet to match the caloric intake of LF rats, and with body weights and adiposity levels comparable to those of LF rats, were also unresponsive to i3vt insulin when returned to ad libitum food whereas rats pair-fed the LF diet had reduced food intake and body weight when administered i3vt insulin. Insulin's inability to reduce food intake in the presence of the high-fat diet was associated with a reduced ability of insulin to activate its signaling cascade, as measured by pAKT. Finally, i3vt administration of insulin increased hypothalamic expression of POMC mRNA in the LF- but not the HF-fed rats. We conclude that consumption of a HF diet leads to central insulin resistance following short exposure to the diet, and as demonstrated by reductions in insulin signaling and insulin-induced hypothalamic expression of POMC mRNA.     

Chronic food restriction and reduced dietary fat: risk factors for bouts of overeating

The purpose of this study was to determine the effect of chronic food restriction and reduced dietary fat on feeding behavior and body weight. Young female rats were fed ad lib or food restricted on a low-fat (LF) or a fat-free (FF) diet for 4 weeks. Rats then received 24-h free access to 2 diets, the maintenance diet (LF or FF) plus a novel high-fat (HF) diet (24-h intake test). After the test, all the rats were allowed chronic free access to the HF diet until body weight was stable. During the 24-h test, the restricted groups ate significantly more calories than the ad lib groups, and the FF-restricted rats ate significantly more total food, carbohydrate and protein than the LF-restricted rats; there were no differences between the two ad lib groups. During chronic free access to the HF diet, the formerly restricted rats achieved and defended lower body weights than the formerly non-restricted rats. Throughout the experiment, the ad lib groups had more body fat than the restricted groups independent of the dietary subgroup. Hence, a history of chronic food restriction predisposes to consuming more food in acute feeding situations, particularly when dietary fat is reduced, and lowers the level of body weight maintained and defended. Chronic food restriction accompanied by reduced dietary fat may increase risk for bouts of overeating.     

Differential Circadian Eating Patterns in Two Psychogenetically Selected Strains of Rats Fed Low-, Medium-, and High-Fat Diets

Spontaneous eating patterns in male, inbred Roman high- and low-avoidance rats (RHA/Verh, RLA/Verh) were continuously recorded while animals were successively offered three isocaloric (16.5-kJ/g) diets: a low-fat, high-carbohydrate diet (LF; 3.3% fat), a medium-fat diet (MF; 18% fat), and a high-fat diet (HF; 40% fat), the latter being followed once again by the LF diet. Under the conditions of this experiment, overall 24h food intake did not differ significantly between RHA/Verh and RLA/Verh rats, but was significantly higher for both rat strains on the MF and HF diets than on the LF diet. Despite the similar 24h-food intake, RHA/Verh rats ate transiently less than RLA/Verh rats during the third quarter of the dark phase under all dietary conditions. These differences were due to the RHA/Verh rats' longer intermeal intervals (with all diets) and smaller meals (with the MF and HF diets) and were compensated for during the last 3 h of the dark phase. On the LF diet, dark-phase meal frequency was higher and both nocturnal meal size and mean eating rate within meals were lower in RLA/Verh rats than in RHA/Verh rats. With the MF and HF diets, mean nocturnal meal size and meal duration were higher and mean eating rate was lower in RLA/Verh rats than in RHA/Verh rats. For both strains, nocturnal meal size was significantly higher with the MF and HF diets than with the LF diet, and nocturnal meal frequency was lower with the HF diet than with the other two diets. Although body weights were similar at the start of the study, RLA/Verh rats gained significantly more weight than did RHA/Verh rats by the end. As has often been the case with other aspects of behavior studied, differences in neuromodulatory systems (e.g., serotoninergic and dopaminergic) between RHA/Verh and RLA/Verh rats may directly or indirectly contribute to the subtle differences in eating patterns observed here.     

Energy-restricted pair-feeding normalizes low levels of brain-derived neurotrophic factor/tyrosine kinase B mRNA expression in the hippocampus,but not ventromedial hypothalamic nucleus,in diet-induced obese mice

Brain-derived neurotrophic factor (BDNF) and its receptor tyrosine kinase B (TrkB) are closely associated with the regulation of energy homeostasis, but their roles in diet-induced obesity have not been explored. Using dietary interventions, this study examined regional changes of BDNF and TrkB mRNA expression in different brain regions of diet-induced obese (DIO) and resistant (DR) mice in response to high-fat (HF), energy-restricted pair-feeding and low fat (LF) diets. Using in situ hybridization, DIO mice had significantly decreased levels of BDNF mRNA expression (−32% to −37%) and TrkB (−21% to −23%) in the hippocampus compared to DR mice on an HF diet, but not on energy-restricted pair-feeding and LF diets. In the ventromedial hypothalamic nucleus (VMH), BDNF expression was decreased in DIO mice on HF (−23%) and energy-restricted pair-feeding (−21%) diets. Furthermore, the VMH BDNF expression was negatively correlated with blood glucose but positively correlated with plasma adiponectin. These findings suggest that decreased hippocampal BDNF and TrkB expression plays an important role in high-fat diet induced obesity. A lower baseline BDNF mRNA expression in the VMH of DIO mice after normalization of body weight may indicate their intrinsic nature or an elevated body weight set point to drive body weight gain.     

Diet composition alters the satiety effect of cholecystokinin in lean and obese Zucker rats

Although exogenous administration of the peptide cholecystokinin (CCK) has been shown to reduce food intake in a variety of experimental situations, few studies have examined the influence of dietary content upon CCK's effectiveness, particularly in obese states. To evaluate the effectiveness of CCK administration in animals consuming high fat diets, groups of obese and lean Zucker rats were maintained on laboratory chow (CH), a high fat diet isocaloric to chow (IF), or a hypercaloric fat diet (HF). After a 17 hr fast, rats were given intraperitoneal injections of saline or ascending doses of 0.06 to 2.0 micrograms/kg of the synthetic octapeptide of CCK. On all diets, obese rats required higher doses of CCK to significantly reduce feeding and showed smaller intake reductions than lean rats (p less than 0.001). Despite higher baseline caloric intakes (p less than 0.001), rats of both genotypes maintained on HF displayed larger reductions of intake than those fed IF or CH (p less than 0.001). Intake reductions by either genotype maintained on IF or CH were not reliably different. The manner in which the satiety effect of CCK was enhanced in rats consuming the calorically dense, palatable HF diet is unclear but may be related to orosensory and/or postingestive attributes of the diet.     

Effects of diet composition on food intake and carcass composition in rats

Since most of the weight-reduced obese humans are in a protein deficit state, this study was designed to examine whether a high protein diet (HP) enhances the restoration of lean body mass and facilitates the maintenance of weight loss. Obesity in rats was produced by 16 weeks of high fat diet (HF) feeding. In the 17th week, all HF-fed obese rats were fed a limited amount of control diet to normalize their body weights, but they still had more body fat content. The HF-fed rats were then divided into subgroups with different diets offered for 5 weeks: HP, HF or chow diet. A control group was fed the chow diet throughout the study. HP feeding maintained normal body weight and carcass composition in weight-reduced obese rats by reducing feeding efficiency levels to within normal ranges. Weight-reduced rats fed a chow diet, however, had more fat mass than controls and HF feeding stimulated weight gain again. Therefore, a HP diet has a higher probability of enhancing weight loss maintenance in weight-reduced obese subjects than does a usual well-balanced diet.     

不同脂肪含量的高脂纯化配方饲料对大、小鼠代谢综合征发生的影响

 摘要： 目的 探讨不同脂肪含量的高脂纯化配方饲料对大、小鼠体重、血糖、血胰岛素、血脂、脂肪肝及白蛋白尿的影响。 方法 雄性SD大鼠及C57BL/6小鼠随机分为MS10%、MS45%和MS60%脂肪含量饲料组,喂养3个月,检测动物体重、血糖、血胰岛素水平、血脂和蛋白尿水平,以及主要脏器重量及肝脏脂质含量。 结果 与正常组（MS10%脂肪含量）相比,高脂组（MS45%和MS60%脂肪含量）动物体重显著增加,出现明显的糖耐量异常、胰岛素抵抗和血脂水平升高,同时伴有肝脏脂质含量和蛋白尿水平的增加,并且以MS45%高脂组体重增加及胰岛素抵抗更加显著。 结论 MS45%和MS60%高脂配方饲料均可在大、小鼠较好地诱导代谢综合征的发生,而且前者优于后者。 关键词： 高脂饲料;胰岛素抵抗;肥胖;代谢综合征     

Maintenance on a high-fat diet impairs the anorexic response to glucagon-like-peptide-1 receptor activation

Previous data suggests that the adiposity signal leptin reduces food intake in part by enhancing sensitivity to short-term signals that promote meal termination, including glucagon-like peptide 1 (GLP-1). We hypothesized that maintenance on a high-fat (HF) diet, which causes resistance to leptin, would impair GLP-1's ability to reduce food intake. To test this hypothesis, we examined the anorexic responses to intraperitoneal injection of 100 μg/kg GLP-1 and 1 μg/kg exendin-4 (Ex-4), the potent, degradation resistant GLP-1 receptor agonist, in Wistar rats maintained on a low-fat (10%; LF) or HF (60%) diet for 4-6 weeks. Rats maintained on each of these diets were tested twice, once while consuming LF food and once while consuming HF food, to distinguish between effects of acute vs. chronic consumption of HF food. LF-maintained rats tested on LF diet reduced 60-min dark phase intake in response to GLP-1, but HF-maintained rats failed to respond to GLP-1 whether they were tested on HF or LF diet. LF-maintained rats tested on HF diet also showed no response, suggesting that even brief exposure to HF diet can impair sensitivity to GLP-1 receptor activation. Both LF- and HF-maintained rats showed significant anorexic responses to Ex4 at 4 h post-treatment, but only LF-maintained rats had significantly reduced intake and body weight 24 h after injections. To determine whether the ability of endogenous GLP-1 to promote satiation is impaired by HF maintenance, we examined the response to exendin 3 (9-39) (Ex9), a GLP-1 receptor antagonist. In LF-maintained rats, Ex9 increased intake significantly, but HF-maintained rats reduced food intake in response to Ex9. These data support the suggestion that maintenance on HF diet reduces the anorexic effects of GLP-1 receptor activation, and this phenomenon may contribute to overconsumption of high-fat foods.     

Long-term effects of exogenous leptin on body weight and fat in post-obese female rats.

This study was designed to test the hypothesis that short-term leptin infusion during the post-obese refeeding phase of weight-reduced rats would reduce the rate of weight regain and, as a result, reduce the final body weight and fat content in weight-reduced rats. Ninety-six female Wistar rats were divided into four groups: (1) LFCON (low-fat control) group: Rats in this group were fed the control low-fat (LF) diet ad lib for the entire study period. (2) HFCON (high-fat control) group: Rats in this group were fed the high-fat (HF, 40% fat) diet ad lib for the study period. (3) HFRLP (high-fat fed, weight-reduced, leptin treatment) group: Obese rats in this group were weight-reduced and received leptin infusion for 2 weeks (miniosmotic pumps, 0.5 microg/kg/day) during the post-obese refeeding period. (4) HFRSM (high-fat fed, weight-reduced, sham control) group: Rats in this sham-control group were treated the same as the rats in the HFRLP group with the exception that no leptin was actually infused during the first 2 weeks of refeeding period. The results demonstrated that 2 weeks of leptin treatment during the early refeeding phase did not prevent weight regain in weight-reduced rats, but it significantly reduced body fat content in these rats as compared to ad lib fed obese control rats. One cycle of weight reduction and regain did not alter the body weight and body fat content in HFRSM rats when compared to obese control rats. Therefore, leptin treatment was effective in reducing body fat content in post-obese rats for up to 7 weeks, but the long-term effect of short-term leptin treatment needs to be further examined.     

Sex differences in high fat-induced obesity in rats: Effects of 18-methoxycoronaridine

Evidence suggests that the development of diet-induced obesity in males and females might be mediated by distinct mechanisms, warranting different treatment approaches. In previous studies from this laboratory, a high sucrose diet induced excessive weight gain in female but not in male Sprague-Dawley rats, while weight gain in both sexes was similarly attenuated by the administration of a selective antagonist of α3β4 nicotinic receptors, 18-methoxycoronaridine (18-MC). In the present study, assessment of high-fat induced weight gain, consummatory behavior and biochemical markers of obesity was conducted in male and female Sprague-Dawley rats and the effects of 18-MC treatment were compared in the two sexes. Male rats consuming a high-fat (HF) diet developed excessive weight gain and fat deposition compared to same same-sex controls fed with a low-fat (LF) diet. The development of obesity in these rats was attenuated by repeated administration of 18-MC (20mg/kg, i.p.), which significantly reduced their food intake without altering water intake. In contrast, female rats consuming a HF diet did not become obese and did not respond to 18-MC treatment. These results show that males and females are differentially responsive to HF-induced obesity; the 18-MC data suggest that α3β4 nicotinic receptors may participate in maintaining obesity, possibly becoming a new and important target for anti-obesity agents.     

Relationship of dietary fat content to food preferences in young rats

Weanling rats were fed either a high-fat (30% of calories) or a low-fat (10% of calories) diet for four weeks, after which fat preference was assessed using a choice paradigm. Fat preference was measured during 2-hour intake tests in which three peanut butter/peanut oil mixtures containing 0.50, 0.61, and 0.71 grams fat/gram were offered to each animal. Rats fed the high-fat (HF) diet preferred the highest-fat mixture and consumed more total fat during intake tests than animals fed the low-fat (LF) diet. Intake of NaCl and sucrose solutions was measured during separate intake tests. LF-fed rats drank more NaCl solution than HF-fed rats. Following these tests a subgroup of the LF-fed animals was fed the HF diet, and a subgroup of the HF-fed group was fed the LF diet for a further four weeks. Upon repetition of the intake tests, rats that had been fed the HF diet during the initial four weeks still preferred the highest-fat mixture.     

Effects of alternations (10 days) of high-fat with normal diet on liver lipid infiltration, fat gain, and plasma metabolic profile in rats

The purpose of the present study was to test the hypothesis that short-term alternations of high-fat with normal chow feeding result in higher fat accumulation in liver than continuous intake of the same high-fat diet. Male Sprague-Dawley rats (7 weeks of age) were divided into 3 groups according to diet composition: standard chow (SD; 12,5% kcal as fat), high-fat (HF; 42% kcal as fat), and food cycles (FC) consisting of 10-day alternations between HF and SD diets beginning with the high-fat diet. Rats in each of these 3 groups were sacrificed after 10, 30, and 50 days (n = 10 rats/sub-groups). Energy intake, body weight, liver and muscle relative weights were not significantly (P > 0.05) different between FC- and HF-fed rats. Using the total energy intake for the 50-day period, it was calculated that approximately 30% less calories as fat was ingested in the FC- compared to the HF-fed rats. In spite of this, liver lipid infiltration as well as fat accretion in abdominal adipose tissues were increased (P < 0.01) similarly in FC- and HF-fed rats. Plasma FFA and insulin levels depicted strong tendencies (P < 0.07) to be higher in FC- than in continuous HF-fed rats at the end of the 50-day period. These results indicate that, despite a 30% reduction in ingested lipids, alternations of HF with normal chow diet compared to the continuous hyperlipidic diet caused the same level of infiltration of lipids in the liver and in the abdominal adipose tissues and, to a certain extent, may even result in a larger deterioration of the metabolic profile.     

Dietary hyperphagia in rats: role of fat, carbohydrate, and energy content

Dietary energy, fat and carbohydrate content were varied to determine the nutritional factors responsible for hyperphagia induced by feeding rats high-fat diets. In the first experiment, rats were fed isoenergetic high-fat or high-carbohydrate diets for 2 weeks. Weight gain and energy intake were lower in rats given the high-fat diet. When some of the rats were switched to a diet that was high in fat, carbohydrate and energy, gram food intake was initially unchanged, resulting in a substantial increase in energy intake and weight gain. Energy intake gradually declined over the 4 weeks following the switch to the high-energy diet. In the second experiment, rats were fed high-fat diets that were either high or low in carbohydrate content and either high or low in energy content (kcal/g). Rats fed a high-fat diet that was high in energy and carbohydrate ate the most energy and gained the most body weight and carcass fat. In the third experiment, rats were fed high-carbohydrate diets varying in fat and cellulose content. Energy intake and body weight gain varied directly as a function of caloric density regardless of the fat or cellulose content of the diets. It is concluded that hyperphagia induced by feeding high-fat diets is not due to the high dietary fat content alone. Rather, high levels of fat, carbohydrate, and energy interact to produce overeating and obesity in rats fed high-fat diets.     

Post weaning high fat feeding affects rats' behavior and hypothalamic pituitary adrenal axis at the onset of puberty in a sexually dimorphic manner

Feeding adult rats with high fat (HF) diets can alter their hypothalamic pituitary adrenal (HPA) axis responsiveness. In the present study, we examined the effect of a high fat diet, applied in rats from weaning to puberty, on their behavior and HPA axis status at puberty onset. Wistar rats of both sexes were fed postweaning with two diets containing either 24% fat (high fat, HF) or 4.3% fat (normal chow) by weight. HF enhanced puberty onset in female rats, without increasing body weight gain in either sex, compared with chow-fed animals. In the forced swim test, HF males exhibited a more active behavioral response on the first day, whereas HF females a more passive response during the second day of the test, as compared with their chow-fed counterparts. In the open field test, HF females showed increased sniffing but reduced rearing, compared with chow-fed females and were less explorative than HF males in the central arena. All animals could learn and recall a water maze task though HF males spent more time in the opposite quadrant than chow-fed males during memory test. The HPA axis status of these animals was investigated under basal conditions. Pubertal fat-fed males had lighter adrenals, while females heavier ones, compared with their counterparts. In addition, plasma corticosterone levels of female rats were increased and glucocorticoid receptor levels in their hypothalamus were reduced due to fat diet, while in males no such changes were detected. We conclude that HF feeding during the prepubertal period can affect behavior and the HPA axis of rats at puberty onset, well before the appearance of the obese state, in a sexually dimorphic manner. Fat diet impacted more the female HPA axis, suggesting that their system is more sensitive to fat-induced nutritional imbalance during adolescence. Present data suggest that the fat-induced nutritional imbalance in young females may lead to neuroendocrine dysfunction that in turn may trigger the appearance of stress-related disorders during adolescence.     

Effect of a beta-3 agonist on food intake in two strains of rats that differ in susceptibility to obesity

CONTEXT: Beta-3 agonists acutely reduce food intake, but the mechanism is not well understood. OBJECTIVE: To evaluate the effect of a beta3 agonist on food intake in two strains of rats that differ in their sensitivity to becoming obese while eating a high-fat (HF) diet. METHODS: Male Osborne-Mendel (OM) and S5B/Pl (S5B) rats were treated with a beta3-adrenergic agonist (CL 316,243) at 8 weeks of age, after an adaptation to either an HF (56% fat energy) or a low-fat (LF; 10% fat energy) diet that was equicaloric for protein (24% energy). Ad-lib-fed rats were injected intraperitoneally with CL 316,243, at doses of 0.03, 0.1, 0.3, 1.0 or 3.0 mg/kg, or with vehicle at the beginning of the dark cycle. Food intake was measured at 1, 3, 6 and 24 h after injections. RESULTS: The beta3 agonist CL 316,243 significantly decreased food intake at all timepoints in both strains of rats eating both diets. However, this inhibition of food intake was significantly greater in the S5B rat. CL 316,243 significantly decreased serum leptin and serum glucose in both the OM and the S5B rats, and again, the inhibition was greater in the S5B rat. Whereas CL 316,243 increased serum insulin levels in the OM rat, it decreased them in the S5B rat on an LF diet. In a second experiment, chow-fed rats were implanted with vascular ports into the jugular vein and allowed to recover. When CL 316,243 was injected into the animals that were fasted overnight, rats of both strains significantly increased their serum insulin at 30 min, but the increase was much more pronounced in the S5B rat. Serum glucose was decreased significantly at both the 30- and 60-min timepoints in the OM rat and at 30 min in the S5B rat. CONCLUSION: These experiments demonstrate that a beta3 agonist (CL 316,243) has a much greater effect in a strain of rats that resist fat-induced obesity.     

Behavioral and physiological responses to stress are affected by high-fat feeding in male rats.

Interactions between monoaminergic neurochemistry and macronutrient intake have been frequently shown. Because monoaminergic systems in the brain are also closely involved in behavioral and physiological stress responses it can be hypothesized that differences in the macronutrient composition of diets are reflected in these responses. The present studies, therefore, were designed to assess the consequences of a change in dietary macronutrient composition on a variety of physiological and behavioral responses (both acute and long-term) to a number of stressors. The effect of chronic high-fat (HF; 61% kcal from fat) feeding on the stress responses was compared with controls receiving regular high-carbohydrate (HC; 63% kcal from carbohydrates) laboratory chow. Rats were kept on this diet for at least 2 months before they were exposed to either psychological (social defeat) or physiological (lipopolysaccharide, LPS, administration) stress. At baseline, chronic HF feeding caused a slight, but significantly reduction in body temperature relative to that observed in HC-fed rats. Following social defeat or LPS injection, HF feeding caused a faster recovery of the body temperature increase relative to animals on the HC diet. Stress-induced suppression of home cage locomotor activity and body weight gain were also reduced by HF feeding. The serotonergic 5-HT(1a) receptor hyposensitivity that was observed in HC-fed rats 2 weeks after stress was absent in the HF regimen. Although the present results cannot be readily interpreted as showing purely beneficial effects of high-fat diets on stress responsivity, the findings in the present study do encourage further investigation of possible ameliorating effects of high-fat diets on aspects of the behavioral and physiological response stress.     

Influence of early dietary experience on energy regulation in rats

The environmental mechanisms that have contributed to the rapid increases in overweight and obesity in the US over the past 25-30 years have yet to be fully specified. One hypothesis that has been forwarded is that increased consumption of calories in liquid form may be a contributing factor, since some studies support the idea that caloric compensation is less adequate for liquid calories compared to calories delivered in more solid form. Work from our laboratory using rats has examined the role that differences in diet viscosity may play in altering energy intake and body weight regulation. This work has suggested that when offered diets matched on caloric density, macronutrient and micronutrient composition, and differing only in viscosity, adult rats fail to compensate for calories delivered in low-viscosity form in short-term intake tests. Further, long-term consumption of low-viscosity diets leads to enhanced weight gain in adult rats. In the present studies, we examined whether short- or long-term exposure to varying relationships between viscosity and calories led to altered food intake or body weight regulation in juvenile rats. The results demonstrated that animals given either short- or long-term experience with direct relationships between viscosity and calories (high viscosity, high calorie meals and low viscosity, low calorie meals) did not differ in food intake or body weight gain compared to animals given short- or long-term experience with indirect relationships between viscosity and calories (high viscosity, low calorie meals and low viscosity, high calorie meals). When juvenile rats were given long-term (9 weeks) exposure to a single, high or low viscosity diet supplement, matched on caloric density and differing only in viscosity, there were no effects on body weight gain. However, analysis of body composition using DEXA demonstrated that animals consuming the low viscosity supplements had significantly greater body fat than animals that consumed either the high viscosity supplement or no dietary supplement at all. These differences in body fat persisted for at least 3 months following the cessation of dietary supplements; during this 3-month period, animals previously exposed to the low viscosity supplement also gained significantly more weight than animals previously exposed to the high viscosity supplement. Taken together, the results suggest that consuming calories in low viscosity form may contribute to poor intake regulation over the short-term and to increased adiposity over the long term. When animals experience these diets as juveniles, these effects may persist into adulthood.     

Comparison of metabolic alterations in hypothalamic and high fat diet-induced obesity.

The heterogeneous nature of the experimental obesities induced by ventromedial hypothalamic (VMH) lesion and high fat diet (HFD) have been demonstrated by comparing VMH-lesioned and sham-operated rats fed a HFD or low fat diet (LFD). VMH rats had increased fat mass serum insulin and serum triglycerides but lower serum glucagon and smaller salivary glands than sham-operated animals. The body weight of HFD obese rats was intermediate between VMH and sham-operated animals on the LDF. Liver and fat pad weights showed effects of lesions and diet. Diet did not affect plasma glucagon or insulin. Pair-feeding VMH rats with sham-operated rats prevented weight gain but did not prevent the increase in insulin and fall in glucagon. Studies of insulin secretion from isolated perifused islets showed that basal and both phases of stimulated secretion were significantly increased in VMH groups. The changes in plasma insulin, plasma glucagon, and salivary gland weight in VMH groups are interpreted as showing decreased activity of the sympathetic nervous system following VMH lesions.     

Hypophagia following dietary obesity

Two experiments examined the hypophagia that occurs when rats are switched from a high-fat to a low-fat diet. In the first experiment, rats fed a high-fat diet for eight weeks weighed 79 g more than rats fed a low-fat diet. Removal of the high-fat diet led to reduced food intake for at least four weeks. Reducing the body weight of the rats by a 24 hour fast did not alter the time course of the hypophagia. Plasma levels of free glycerol, free fatty acids and ketones were elevated during and after feeding the high-fat diet; suggesting that feeding a high-fat diet increases fat oxidation even after the high-fat diet is withdrawn. In the second experiment, feeding rats the high-fat diet for four weeks increased body weight and body fat. Starving the rats for two days after feeding the high-fat diet did not alter subsequent hypophagia and did not alter the percentage of body fat. This pattern of results is similar to that previously seen following termination of obesity-inducing insulin treatment. The results are consistent with the idea that a persistent increase in fat oxidation is responsible for the hypophagia.     

Self-selecting albino rats exhibit differential preferences for pure macronutrient diets: Characterization of three subpopulations

Analyses of natural feeding behavior in albino male Sprague-Dawley rats demonstrate that, when allowed to self-select from pure macronutrient diets (protein, carbohydrate and fat), these rats of the same genetic strain can be categorized into 3 subpopulations according to either their 24-h or their 12-h nocturnal patterns of nutrient intake. A majority of the animals (HC for high carbohydrate, 50% of the total population) consumed a diet rich in carbohydrate relative to protein or fat, while a smaller population of rats (HF, 30%) preferred the fat diet, and an even smaller population (HP, 20%) chose a high-protein diet. These 3 subpopulations, after a few weeks of maintenance on the diets, differed in their body weight, with the HF rats having a higher body weight than the HP animals, who tended to weigh more than the lightest HC rats. Whereas all subgroups exhibited a similar bimodal distribution of feeding during the nocturnal cycle, with peaks during the early and late dark periods, they were distinguishable on the basis of their nutrient consumption during specific phases of the dark cycle. This difference was most apparent in the early dark phase, when the 3 subgroups exhibited exaggerated preferences for the specific nutrient that was generally preferred over the 24-h cycle. This is in contrast to the middle dark phase, when diet preferences were attenuated or lost, and the late dark phase, when most rats were similar in showing an increased preference for protein and fat and a decreased preference for carbohydrate. The HF group was further distinguished by an unusually strong burst of feeding during the first 2 h of the dark period and an extra peak of feeding in the middle dark period (7th h), both of which were relatively high in fat content.