Dietary self-selection vs. complete diet: body weight gain and meal pattern in rats.

Food intake and body weight gain of male adult Wistar rats were examined in two groups of animals. One group (n = 14) was allowed to select its diet from separate sources of protein (casein, 3.1 kcal/g), fat (lard and sunflower oil, 7.9 kcal/g) and carbohydrate (CHO, starch and sucrose, 3.3 kcal/g). Another group (n = 10) received a nutritionally complete diet (3.3 kcal/g). After 2 weeks of adaptation to the diets, body weights and meal patterns were recorded for at least 4 days. The total caloric intake was nearly identical for the two groups of rats. Rats given dietary choice gained less weight over 4 days than rats fed chow and showed reduced feed efficiency. During the 24-h period, self-selecting rats consumed 20.8% of calories as proteins, 21% as fats and 58.2% as CHO. Self-selecting rats ate significantly less calories during the day than did rats given chow. The chow diet consisting of 17.3% calories as protein, 7.6% as fat and 75.1% as CHO. When comparing the self-selecting group nutrient intakes to those of chow-fed group it was observed that 24-h protein calorie intakes were identical in both groups. Fat intake was significantly higher and CHO reduced as compared to chow-fed rats. During the day, CHO intake was higher in self-selecting rats, and fat intake was not significantly reduced. During the night, protein and fat intakes were significantly higher in self-selecting rats, while CHO intake was significantly decreased, particularly in the last periods of the night.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dietary fat-induced hyperphagia in rats as a function of fat type and physical form

The influence of dietary fat on food intake and weight gain was assessed by feeding adult female rats diets that differed in the type and form of fat, as well as in the availability of other macro- and micronutrients. Compared to chow-fed controls, the various fat diets increased total food intake by 4% to 27%. Specifically, rats fed chow and a separate source of fat (fat option diet) consumed more fat and total calories, and gained more weight when the fat source was emulsified corn oil rather than pure corn oil or was vegetable shortening rather than corn oil. However, corn oil and shortening had similar effects on caloric intake and weight gain when presented as emulsified gels. Also, pure and emulsified-gel forms of shortening did not differ in their effects on caloric intake and weight gain. Supplementing the vegetable shortening with micronutrients, however, enhanced its hyperphagia-promoting effect. The results of two-choice tests revealed that the rats' preferences for the orosensory properties of the various fat sources did not account for the differential hyperphagias obtained. Rather, it appears that long-term fat selection and caloric intake are influenced primarily by postingestive factors. Fat selection and total intake were determined not only by the fat source itself, but also by the other diet options. That is, rats selected more fat and consumed more calories when chow was the alternative food than when separate sources of carbohydrate and protein were available.     

Somatic and metabolic responses of mature female rats with dietary obesity to dorsomedial hypothalamic lesions: Effects of diet palatability

Caloric intake, body weight, obesity status (Lee Index) and incorporation of U-14 C-glucose into liver and retroperitoneal fat pad glycogen and lipid were studied in mature female rats that had received bilateral lesions or sham-operations in the dorsomedial hypothalamic nuclei (DMN) after dietary obesity was well established. Their diet consisted of a high-fat-sucrose chow mix, chocolate chip cookies and a drinking fluid of 32% sucrose in tap water. Comparable groups of DMN lesioned rats (DMNL rats) and sham-operated controls were maintained on lab chow pellets and tap water. Prior to the hypothalamic operation, the animals on the high-caloric regimen consumed significantly more calories than the rats on lab chow and also attained commensurately higher body weights and obesity indices. The bulk of the calories consumed during this time was derived from the cookies. Following DMNL, the animals maintained on lab chow became hypophagic and had lower body weights than the sham-operated rats, as has been previously reported. In rats on the high-caloric regimen, DMNL resulted in hyperphagia in comparison to all other groups. The greatest percentage of the calories during this time was derived from the high-fat-sucrose chow mix and sugar water. Correspondingly, DMNL rats on the high-caloric regimen had higher body weights and obesity indices than all other groups. At sacrifice, both a diet and lesion effect were noted in an elevated incorporation of U 14-C glucose in both fat pad and liver lipid and glycogen. The data are interpreted to mean that (1) when a highly palatable, high-caloric diet is available, DMNL do not exert their usual hypophagic and weight-lowering effects; (2) DMNL and control rats show excessive caloric intake when both groups are fed a highly palatable, high-caloric diet in comparison to their chow-fed counterparts. However, DMNL rats fed high-caloric diet also consume significantly more than controls fed this diet; (3) This excessive caloric intake of the DMNL rats possibly predisposes these animals to exaggerated lipogenesis in liver and adipose tissue; (4) the sham-operated controls on the high-caloric regimen also show greater lipogenesis but at a level intermediate between the chow-fed controls and the DMNL rats on the high-caloric diet.     

A carbohydrate diet rich in sucrose increased insulin and WAT in macronutrient self-selecting rats

In order to evaluate the influence of a carbohydrate (CHO) diet rich in sucrose (37%) on food choice and body composition, Wistar rats received a food selection diet (protein, CHO, fat) from the time of weaning to 13 weeks of age. Three groups of animals were examined: the first received a CHO diet containing 37% sucrose; the second, a diet containing only 10% sucrose; and the third, control group, received a complete standard diet (14% protein, 72% CHO including 10% sucrose). Food intakes and body weight (BW) were recorded four times a week. No differences in total food intake were observed between the two self-selecting groups and the control group, and no differences were observed between the two self-selecting groups in terms of their protein intake (about 45% of the total calorie intake). The latter groups modified their selections during the 10-week period, but the variations were similar. BW gain in the 37% group was lower but the white adipose tissue (WAT)/total BW ratio was significantly higher than those seen in the control and 10% groups. Insulinemia was higher in 37% and control groups. In conclusion, the high preferences for protein and fat were identical, whatever the CHO diet composition. The sucrose level in the diet was an essential factor for the development of hyperinsulinemia, leptin resistance and thus a higher prevalence of obesity. These results confirm the importance of the quality of CHO sources in the diet.     

Protein selection, food intake, and body composition in response to the amount of dietary protein

Though not universally observed, moderately low-protein diets have been found to increase caloric intake and body fat. It appears that animals overeat in calories in order to obtain more dietary protein. For animals to control protein intake, they must be able to distinguish between two isocaloric diets containing different percentages of protein and make the appropriate dietary selection on the basis of their previous history of protein intake. Experiment 1 examined the 24-h diet selection (5 vs. 35% casein) of Sprague-Dawley rats that had been previously fed diets containing various percentages of dietary protein (5, 10, 20, 35, or 60% casein). Animals fed 5, 10, or 20% dietary protein showed a preference for the higher protein selection diet. In contrast, no significant diet preference was found in animals pre-fed the two higher levels of dietary protein (35 or 60% casein). In this study, daily food intake and body fat of rats fed the low-protein diets (5 and 10% casein) were similar to rats fed the 20% casein diet. Experiment 2 examined the effects of the level of methionine supplementation on rats fed 10% casein. In this study, food intake and body fat were increased by approximately 20% in rats fed 10% casein diets, regardless of the level of methionine supplementation (0.3 vs. 0.15%). Together, the results suggest that the presence of low-protein-induced hyperphagia helps maintain body protein levels in the face of moderately low dietary protein and promotes an increase in the amount of body fat and energy.     

Lack of diet-induced thermogenesis in brown adipose tissue of obese medial hypothalamic-lesioned rats

Radiofrequency heat lesions were made in the medial hypothalamus of 12-week old male and female Holtzman rats. Two to three days later rats were offered a palatable cafeteria diet in addition to chow or were fed chow alone for the next 3-4 weeks. Male lesioned rats were only slightly hyperphagic on the chow diet and gained little extra weight. When fed the cafeteria diet, energy intake of male lesioned rats almost doubled in comparison with chow-fed lesioned rats and a very rapid extra weight gain occurred. Despite the marked hyperphagia, thermogenesis in brown adipose tissue was suppressed in the cafeteria-fed lesioned rats, as indicated by low mitochondrial guanosine diphosphate (GDP) binding. In female rats, lesions induced much greater hyperphagia and body weight gain than in male rats, particularly when they ate the cafeteria diet. Again, thermogenesis in brown adipose tissue was suppressed in the cafeteria-fed female lesioned rats. The proportion of energy derived from carbohydrate was not altered by the cafeteria diet in either male or female rats, whether lesioned or not, but there was an increase in the proportion of energy derived from fat at the expense of protein. No sex differences in food selection were observed. The accumulation of body fat was always greater in female lesioned rats than in male lesioned rats for similar food intakes. It is concluded that medial hypothalamic lesions prevent the normal occurrence of diet-induced thermogenesis in brown adipose tissue despite extreme overeating by the rats of a palatable cafeteria diet.     

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.     

Patterns of nutrient selection in rats with streptozotocin-induced diabetes

The effects of experimental diabetes on energy intake, patterns of nutrient selection, water intake, body weight and body composition were examined in male Sprague-Dawley rats given ground Purina Chow or a dietary self-selection regime. Following adaptation to dietary conditions, a portion of the animals in each diet group were made diabetic by the administration of 45 mg/kg streptozotocin (STZ). The remaining animals in each group served as vehicle-injected controls. STZ reliably produced diabetes in rats on both dietary regimes. Immediately after the induction of diabetes, rats on the self-selection regime increased carbohydrate and protein intakes and decreased fat intake. Approximately three weeks after STZ administration, diabetic rats reduced carbohydrate intake and increased fat intake. Diabetic animals in both diet groups were hyperphagic and polydipsic relative to non-diabetic controls. During the first three weeks following STZ injections, energy and water intakes of diabetic animals in the two dietary conditions were similar. However, after this initial period, energy and water intakes of diabetic rats given the self-selection regime were significantly lower than those of diabetic animals given Purina Chow.     

High fructose feeding of magnesium deficient rats is associated with increased plasma triglyceride concentration and increased oxidative stress.

The purpose of this study was to assess whether dietary carbohydrate could differentially influence the consequences of magnesium deficiency with particular emphasis on lipid metabolism and oxidative stress. Rats were fed a sucrose based or starch based diet either adequate or deficient in magnesium for two weeks. Magnesium deficient rats, as compared with rats fed magnesium adequate diets, displayed the usual decrease in plasma magnesium concentration. The classic symptoms of inflammation including hyperaemia, increased number of blood leukocytes and enlarged spleen weight were observed in these rats. Plasma TG and plasma apo B concentrations were also significantly increased. In addition, magnesium-deficient animals presented an increased susceptibility to lipid peroxidation of heart and liver tissues as shown by TBARS concentration. Regardless of magnesium status, sucrose feeding did not affect the magnesium plasma level and inflammatory parameters. Feeding rats the sucrose diets induced hypertriglyceridaemia and increased plasma apo B concentration. Heart and liver susceptibility to lipid peroxidation were significantly increased in rats fed the sucrose diets as compared with those fed the starch diets. Sucrose feeding in magnesium deficient rats was associated with higher plasma triglycerides concentration and higher tissue susceptibility to peroxidation as compared with magnesium deficient rats fed the starch diet. The results emphasised the potential detrimental and additional effect of sucrose feeding and magnesium deficiency on cardiovascular risk. Since the intake of magnesium has been reduced appreciably in industrialised countries while fructose consumption has been rapidly increased, the impact of this eating pattern should be clarified in humans.     

Dietary obesity: differential effects with self-selection and composite diet feeding techniques.

Female rats were given access to casein, cornstarch, and fat in separate cups or a composite diet identical in composition to that chosen by self-selecting rats. After 2 weeks, all rats received granular sucrose ad lib in addition to these other foods. Sucrose availability resulted in increased caloric intake and increased body weight gain in composite-fed rats, but not in self-selectors. Self-selectors maintained caloric homeostasis by decreased consumption of all foods initially, but protein intake recovered to control levels by the third week of treatment.     

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.     

Macronutrient diet intake of the lethal yellow agouti (Ay/a) mouse

To examine the effect of chronic endogenous melanocortin receptor (MC-R) antagonism on macronutrient diet selection, Ay/a mice that ectopically overexpress the MC-R antagonist, agouti, were fed a three-choice macronutrient diet of pure fat, carbohydrate, and protein. Ay/a mice gained more weight and consumed a greater proportion of their daily intake from fat and less from carbohydrate than wild-type littermates did. The increased fat preference was present immediately, and persisted throughout the 7-week long experiment. Protein intake was greater for Ay/a mice; however, the proportion of protein intake to total intake was similar between mouse types. Ovarian fat pads of Ay/a mice comprised a greater percentage of total body weight that that from wild-type littermates. These results suggest that endogenous inhibition of MC-Rs mediate the increased fat intake in growing mice.     

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.     

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.     

Effect of treadmill exercise on food intake and body weight in lean and obese rats

Body weight and food intake of lean and obese, male and female Osborne-Mendel rats following treadmill exercise were compared. Rats were assigned, separately by sex, to one of three diet groups; Group 1 was fed a low fat (10%) diet throughout the study, Group 2 was fed a high fat (55%) diet for 16 weeks and then switched to the low fat diet 1 week prior to exercise, and Group 3 was fed the high fat diet throughout the study. To control for differences in work output between the leanest and heaviest animals, exercise intensity was adjusted across groups such that all exercised rats had equivalent energy expenditure. After a 3 day training period, the exercise was successively increased over 8 days until a work output of 374.9J was reached. Relative to their respective controls, obese exercised males showed a reduction in body weight but no change in food intake. In contrast, exercised females showed no change in body weight or food intake, regardless of dietary condition.     

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.     

Dietary self-selection in intact, ovariectomized, and estradiol-treated female rats

The effects of estrogenic stimulation on diet selection were examined in intact, estrous cycling rats, ovariectomized (OVX) rats, and OVX rats given estradiol benzoate (EB) hormone replacement therapy. In Experiment 1, OVX was associated with the nearly exclusive choice of the more calorically dense diet of a pair of diets varying in the concentration of one of the three basic macronutrients (i.e., fat, carbohydrate, and protein), an effect that was decreased by EB administration. In the second experiment, dietary self-selection was examined in intact, estrous cycling rats given access to an isocaloric diet triplet of fat, carbohydrate (CHO), and protein. Total caloric intake and body weight did not vary across the estrous cycle. However, diet selection did vary. Fat intake increased; CHO and, to a lesser extent, protein intake decreased during estrus. An opposite diet selection occurred during diestrus. In Experiment 3, OVX resulted in progressive increases in CHO and protein intake, with a concurrent decrease in fat consumption. The EB treatment partially reversed this diet selection profile (Experiment 4). These results were confirmed by diet pairs with both naturally occurring and experimentally produced estrogenic stimulation (Experiments 5 and 6). These data are consistent with the findings of previous research demonstrating estrogenic reduction in CHO intake with standard high-CHO commercial diets. In addition, an increase in fat intake during estrogenic stimulation was found.     

Increased carbohydrate intake as a function of insulin administration in rats

Patterns of dietary self-selection were examined in male rats following subcutaneous injections of NPH insulin. Self-selection animals received separate dietary sources of protein, carbohydrate and fat, while single diet animals received ground Purina Rodent Chow. Food intakes and body weights were measured daily. In comparison to non-injected animals, both self-selection and single-diet animals displayed similar increases in caloric intakes and body weights in response to insulin administration. In animals maintained on the self-selection regime, the increase in caloric intake was solely a function of an increase in carbohydrate intake. Neither protein intake nor fat intake varied as a function of insulin administration. While fat intake remained stable in insulin-injected animals, non-injected self-selection animals gradually increased fat consumption throughout the experiment. Termination of insulin administration for all animals led to decreases in caloric intake below the levels of non-injected animals. Again, modification in caloric intakes in selecting animals were primarily a consequence of altered carbohydrate intake. Patterns of dietary self-selection in insulin-injected animals are contrasted to patterns of selection in other forms of experimental obesity.     

Dietary self-selection of golden hamsters in response to acute food deprivation and chronic food restriction

Adult male golden hamsters were maintained on either Purine Rat Chow (Chow diet) or a self-selection diet consisting of high-protein chow, pure fat, and pure carbohydrate (Choice diet). In Experiment 1, animals were deprived of food for single periods of up to 48 hr. Animals on the Chow diet did not increase intake at any time after deprivation; animals on the Choice diet selectively increased their consumption of fat-derived calories and increased their total caloric intake during the first 6 hr of refeeding, but not thereafter. The nature of the diet did not influence the rate at which animals regained weight following deprivation. In Experiment 2, hamsters were placed on food-restriction schedules (access to food either for 1 hr/day only or on alternate days only) until they lost 20% of starting body weight. Chow-fed animals demonstrated little or no change in food intake either during or after food restriction. Hamsters on the Choice diet consumed more calories and lost weight more slowly than did chow-fed animals during 1-hr/day feeding; intake of fat-derived calories was elevated during restriction. Choice hamsters increased total caloric intake only towards the end of the alternate-days restriction schedule. Choice hamsters were hyperphagic following both types of food-restriction schedules, but no increased preference for fat-derived calories was observed. Factors influencing food consumption of hamsters in response to deprivation and restriction are discussed.     

Control of protein intake in golden hamsters

Experiments were performed to investigate the behavioural responses of golden hamsters to manipulations of dietary protein availability. In the first experiment, hamsters were maintained on a protein-free diet and a powdered diet containing 64.8% protein (P64.8). When the P64.8 diet was progressively diluted with cornstarch, hamsters increased their intake of this diet fraction, but protein intake nevertheless declined. When the protein content of the diet was 16.2%, animals derived only 6% of total calories from protein and lost weight despite normal intake of calories. In the remaining experiments, hamsters were maintained on a self-selection regimen of high-protein chow, pure carbohydrate (sugar cubes), and pure fat (vegetable shortening). When high-protein chow was removed for either 5 or 10 days, total caloric intake and body weight declined, and hamsters selectively increased protein intake for several days after high-protein chow was returned. Hamsters allowed access to high-protein chow for only one hour each day markedly increased the amount of high-protein chow they ate during this hour as protein-restriction continued, but still consumed only about 10% of their normal daily protein intake on this schedule and lost 20% of starting body weight in two weeks; when free access to high-protein chow was restored, these animals selectively increased their protein intake above pre-restriction levels. Hamsters given access to high-protein chow only on alternate days demonstrated a relatively modest and slowly developing increase in protein intake, perhaps because they incurred only a moderate protein deficit. The results suggest that when protein intake falls below normal minimum requirements, hamsters will demonstrate an adaptive protein hunger but make only a limited adjustment to the dilution of a protein-containing diet fraction.