Physiological effects of dieting and bingeing in rats.

Female rats were assigned to dietary conditions as follows for 3.5 months: 1) Low-fat control (LFC); 2) Moderately high-fat control (HFC); 3) Alternation between restricted access to a low-fat diet and ad lib access to a very high fat diet (RA); 4) Unrestricted access to the same diets as RA (URA). Results indicate that: 1) HFC consumed the same energy as LFC, but showed a tendency to become heavier and fatter through greater food efficiency. 2) URA and LFC did not differ in body weight, food intake, body composition or energy efficiency. 3) Intake of the very high fat diet declined over time in the RA. 4) RA ate less total calories, weighed less than all other groups, and showed a tendency for decreased percentage body fat and increased percentage of weight gained due to FFM gained. Results provide no evidence that dieting and bingeing promote obesity or increased preference for dietary fat, and suggest that dietary restriction has greater impact on energy balance and body composition than does alternation of diet composition.     

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.     

Weight cycling in female rats increases dietary fat selection and adiposity

The effect of repeated food restriction-refeeding (weight cycling) on macronutrient selection and adiposity was investigated in female Sprague-Dawley rats. Rats were maintained on ad lib macronutrient self-selection and were put on one of two types of restriction. One group was reduced to 75% of their body weight on restricted amounts of chow and a second group was given ad lib chow during the concurrent period and were voluntarily hypophagic. During refeeding on macronutrient self-selection, animals previously restricted selected a higher percentage of dietary fat, had larger adipose depots and plasma insulin values, and had lower heart weights both expressed in grams and as a percentage of body weight than non-restricted groups. This suggests that both severe and moderate periods of restriction may have negative health consequences.     

Effect of hydroxycitrate on food intake and body weight regain after a period of restrictive feeding in male rats

We examined whether dietary supplementation of hydroxycitrate (HCA), a competitive inhibitor of the extramitochondrial enzyme ATP-citrate-lyase, which inhibits lipogenesis, reduces food intake and body weight regain in rats after 10-15% weight loss. In four experiments, 24 male rats were fed restrictively (10 g/day) for 10 days and then given ad lib access to one of four different diets (HI-Suc=high sucrose; HI-Glu=high glucose; Chow=grounded standard rat chow; HI-Glu+Fat=high glucose+fat) varying in the content of fat and low molecular carbohydrates for the following 10 days. For half of the rats (n=12), the ad lib diet was supplemented with 3% (w/w) HCA. HCA reduced body weight regain with all diets except Chow. HCA also reduced food intake temporarily with three of the four tested diets. The suppressive effect of HCA on food intake was particularly strong with the HI-Glu+Fat diet (fat=24% of energy). With Diet HI-Glu and HI-Glu+Fat HCA reduced the feed conversion efficiency (cumulative body weight regain (g)/cumulative food intake (MJ)) during the 10 ad lib days, suggesting that it also increased energy expenditure. This effect seemed to be positively related to the glucose content of the diet. All in all, HCA reduced body weight regain after substantial body weight loss, and the effects are presumably linked to its inhibiting effect on lipogenesis, but the exact mechanism still has to be determined.     

Resting oxygen consumption in over- and underfed rats with lateral hypothalamic lesions

Rats maintaining stable, reduced body weights following lateral hypothalamic (LH) lesions were given either ad lib amounts of a palatable liquid diet or restricted amounts of a hydrated chow diet. The palatable diet produced weight gains while the diet restriction led to weight reductions in both LH- and sham-lesioned rats. Body composition analysis indicated that these changes in body mass were accounted for largely by changes in carcass fat. Resting oxygen consumption (expressed relative to body weight raised to the 3/4 power) was altered by both dietary regimens. Resting oxygen consumption in sham-lesioned rats increased by 5% following overfeeding and decreased by 13% following food restriction. LH-lesioned rats made similar responses to these dietary challenges. Overfed LH-lesioned rats increased their rate of resting oxygen consumption by 11%. Underfed LH-lesioned rats decreased oxygen consumption by 11%. These findings provide further evidence that rats with LH lesions defend a reduced level of body weight. The changes in energy expenditure that mitigate weight change in sham-lesioned animals are also present in LH-lesioned rats. In the latter, however, these adjustments serve to stabilize body weight at a lower level.     

Consumption of a high-fat diet alters the homeostatic regulation of energy balance

Humans in many countries are currently experiencing what has been called an epidemic of obesity. That is, the average body weight (and amount of fat stored in the body) is increasing over years, carrying with it a multitude of associated medical, psychological, and economic problems. While there is no shortage of possible causes of this epidemic, increased availability and consumption of high-fat (HF), calorically dense and generally quite palatable food is often touted as a likely culprit. In order to better assess the impact of consuming a diet with those qualities, we have developed a well-controlled animal model in which the effects of chronic consumption of a high-fat diet can be dissociated from those of becoming obese per se. Long-Evans rats are fed one of two semipurified pelleted diets, a HF diet that contains 20% fat by weight and a low-fat (LF) diet that contains 4% fat by weight. Pair-fed animals consume the HF diet but are limited to the daily caloric intake of LF rats. Another group receives pelleted chow. Relative to animals consuming diets low in fat, HF animals weigh more, have more carcass fat, are hyperinsulinemic and hyperleptinemic, and are insulin resistant. HF-fed animals, independent of whether they become obese or not, also have central insulin and MTII insensitivity. Finally, HF rats have a down-regulated hypothalamic apo A-IV system that could contribute to their hyperphagia.     

Food access schedule and diet composition alter rhythmicity of serum melatonin and pineal NAT activity.

This study investigated the effect of dietary composition and food access schedule on the rhythmicity of serum melatonin and pineal N-acetyltransferase (NAT) activity. Wistar rats maintained on a 12:12 h light-dark cycle were assigned to two dietary groups: a group fed rat chow and a group fed a choice between a protein-rich and a carbohydrate-rich diet. Each dietary group was further divided based on feeding schedule, with food available between 0800 and 1600 h or ad lib access to food. Regardless of dietary condition, total food and carbohydrate intake of rats having free access to food was higher than under the restricted food access schedule. Protein intake of rats fed the dietary choice was lower with the restricted access than in the free access. In rats fed the dietary choice, melatonin levels and NAT activity were significantly decreased with restricted access compared to free access. Such results were not found in rats offered restricted chow. This study suggests that the rhythms of melatonin secretion and NAT activity can be altered by dietary composition.     

Adaptation to water restriction through dietary selection in weanling rats

For each of five pair of diets, 20 weanling rats were equally divided into ad lib and restricted water groups. Caloric density, palatability, as well as nutrient composition of the diet pairs were manipulated. Though lower in absolute food intake than controls, water-restricted rats took a larger proportion of their food from diets lower in protein content and higher in fat content, regardless of caloric content or palatability. The results demonstrate both a quantitative and qualitative dietary adaptation to water restriction.     

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.     

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.     

Overeating,dietary selection patterns and sucrose intake in growing rats

Weanling rats were allowed access to food for either 5 hours or 24 hours per day. Within each food availability condition one group had access to a complete diet and one group had access to the complete diet and a 32% solution of sucrose. Caloric intake and rates of growth were considerably higher in the 24 hour access groups. The availability of sucrose led to a small (10–15%) but consistent elevation in caloric intake in the ad lib condition but did not influence growth in either food availability condition. Absolute levels of sucrose intake and the proportion of calories taken from the sucrose solution were consistently higher in the ad lib group and increased with increases in body size for both groups. Dilution of the chow component or the sucrose component of the diet did not alter dietary selection patterns in either food availability condition. It appears that access to a palatable carbohydrate solution can lead to overeating in the rat but these solutions do not induce the rat to select imbalanced diets that compromise growth.     

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.     

Can overeating induce conditioned taste avoidance in previously food restricted rats?

While feeding is rewarding, the feeling of satiation has been theorized to have a mixed affect. Using a food restriction model of overeating we examined whether bingeing was capable of supporting conditioned taste avoidance (CTA). Adult male Sprague-Dawley rats were maintained on either an ad lib (n = 8) or restricted (50% of regular consumption; n = 24) food access for 20 days. On Days 9, 14, and 19 all rats were given access to a novel saccharin solution in place of water, and two groups of food restricted rats were given access to either 100% of regular food consumption or ad lib food. Ad lib access in the restricted rats induced significant overeating on all three exposures. After all rats were returned to ad lib feeding, a 24 h two-bottle saccharin/water choice test displayed significantly reduced saccharin consumption in the overeating rats, compared to those in the other 3 groups. To determine whether this avoidance was due to a learned association, a second experiment used a latent inhibition paradigm, familiarizing half the rats with the saccharin for 8 days prior to pairing it with overeating. Using the design of Experiment 1, with only the continuously ad lib and the restricted to ad lib feeding groups, it was found that the overeating-induced saccharin avoidance was attenuated by the pre-exposure. These results suggest that self-induced overeating is capable of supporting a learned avoidance of a novel solution suggestive of a conditioned satiety or taste avoidance.     

Effects of aging on food intake and body composition in rats

Alterations in the ability to adjust energy intake when optional dietary foods are available may contribute to aging-related changes in body composition. Ingestive behavior, however, has not been extensively studied in aging models. The present research used young, middle-aged and old rats to examine food intake under several different schedules of optional fat availability. All rats were provided with continuous access to a nutritionally complete diet throughout the 6-week study. In addition, different subgroups within each age had access to an optional source of vegetable shortening under schedules in which the frequency of access was manipulated: controls (C)-- no shortening access; MWF--2-h shortening access on Monday, Wednesday and Friday; D2--2-h shortening access every day; D24--24-h shortening access every day. Energy intake was significantly greater in groups with more frequent access to shortening regardless of age. The length of time the rats remained hyperphagic, however, increased with age. Body weight increased significantly in the D24 group in middle-aged and old rats, but not in young rats. Total body fat was also significantly higher in middle-aged and old groups with more frequent access to shortening, but not in young rats. Finally, body ash mass was significantly reduced in old rats on the D24 diet. These results suggest that alterations in responses to an optional source of dietary fat may contribute to aging-associated body fat accretion and body mineral loss.     

Food selection during recovery from protein restriction in lactation.

Lactating rats were fed a 12% or 25% casein diet. After the pups were weaned on Day 21, dams were given ad lib access to three food cups containing protein, carbohydrate, and fat. Both groups were hyperphagic for three to four weeks. Previously, protein-restricted rats consumed more protein than controls during Weeks 2 and 3, but protein intake returned to control levels as body weight recovered.     

Obesity without overeating in golden hamsters

When male golden hamsters were switched from a diet of Purina rodent chow to a calorically-dense high-fat diet or were given ad lib access to a 32% sucrose solution in addition to chow, they adjusted their food intakes rapidly (within 24 hr) and did not overeat. Nevertheless, the fat-fed hamsters tripled their rate of weight gain and nearly doubled their carcass fat content after one month on the diet. Resting oxygen consumption (animals awake but quiet) was significantly lower in fat-fed animals than in chow-fed controls. Sucrose feeding had no effect on food intake, body weight gain, carcass composition or oxygen consumption. Thus, whereas rats exhibit dietary obesity in spite of increases in energy expenditure (diet-induced thermogenesis), fat-fed hamsters seem to become obese because of decreases in energy expenditure. However, although actual energy expenditure is reduced, fat-fed hamsters exhibit an enhanced thermogenic capacity. Interscapular brown adipose tissue mass, protein content, and DNA content as well as norepinephrine-stimulated oxygen consumption were all significantly elevated in fat-fed hamsters. The significance of these concurrent diet-induced decreases in energy expenditure and increases in thermogenic capacity is not clear, but they could be of some value in preparing the hamster for winter.     

Energetic responses of pigeons during food deprivation and restricted feeding

Pigeons ate food ad lib, then fasted for several days, and finally ate a controlled amount of food once a day for several months to maintain body weight at 80% of the ad lib value. Whole-body dry heat loss (HL) and core body temperature (Tb) were measured continuously for each pigeon. Thermal conductance (C) was calculated from HL and Tb. Relative to ad lib feeding, 24-h HL was reduced by approximately 50% during fasting and controlled feeding. The majority of energy savings was achieved by lowering C, which appeared to maintain a saturated low value throughout most of the light and dark phases. Therefore, the pigeon's characteristic high Tb in the daily light phase during fasting and food restriction does not necessarily imply high energy expenditure. In the dark phase, the fasting pigeon's characteristically low Tb enhances energy savings already being achieved through lowered C. The daily cycle in Tb, and to a lesser extent in HL and C, was strongly altered by occasional probe variations in the amount of food given at the single daily feeding and by a shift in the time of the daily feeding.     

Long-term dietary restriction causes negative effects on cognitive functions in rats

Long-term dietary restriction is reported to increase life span and improve age-related cognitive deficits. The present study shows that the restriction increases the life span of rats but decreases their cognitive ability. Thirty-two rats were divided into restricted and ad lib feeding groups at 2.5 months of age. The restricted rats were kept at a weight of 280g. The restricted rats were poor in performing the Morris water maze task at 7-12 months. At 17-18 months, they were poor in performing the delayed matching-to-place task. At 24-27 months, the surviving 13 restricted and 5 ad lib rats performed the spatial discrimination task. The restricted rats were also poor in performing this task. Injection of glucose prior to the discrimination task improved their performance to the level of the ad lib rats. These results suggest that dietary restriction is beneficial for longevity but has negative effects on the performance of cognitive tasks, and that the cause of the negative effects may be a reduced availability of glucose in the food-restricted aged rats.     

Taste or diet balancing?

Two groups of adult male rats were given ad lib access to a nutritionally complete diet (Purina Chow) and either a 32%-sucrose solution (w/v) or a separate container of dextrinized starch. A control group was allowed access only to Purina Chow. All groups consumed the same total caloric intake. Further, the composition of the diets selected by the two carbohydrate groups did not differ, although rats with access to sucrose gained weight at a signficantly greater rate than the starch group or the control group. These results suggest that the balance between dietary items plays an important role in the selection of food items and that the mechanism used in determining balance is not based on factors such as taste or feedback from body weight.     

Long term effects of quinine on food intake and body weight in the rat

Adulteration of a chow diet with 0.75% quinine sulfate produces a short-lived decrement in food intake in both ad lib-fed and previously food-restricted adult female rats. In contrast, quinine produces a long-lasting depression in body weight; ad lib access to quinine-treated chow results in a plateauing of body weight at a lower level until quinine is removed from the diet, despite recovery of food intake.