Effects of hydrational state on ingestion in infant rats: is dehydration the only ingestive stimulus?

Hypothalamic peptide and nutrient sensors gene expression in the hypothalamus of neonatal rat

In the neonate, the main mediator for satiety or hunger is the information of distention or gastric contraction. Food intake controls has two types of a short-term one, based on the level of hydration, and another long-term one, dependent on the gastric stretch. The aim of this study is to evaluate the gene expression of peptides and nutrient sensors in the hypothalamus at 10 and 18 days of postnatal life. Male rats divided into groups: Fasting, Water, Milk, and Gavage.Two age groups had analyzed into 10 and 18 days. Gene expression of hypothalamic peptides, Neuropeptide Y(NPY), Agouti-related peptide(AgRP), proopiomelanocortin(POMC), cocaine-and amphetamine-regulated transcript(CART), and energy sensors mechanistic target of rapamycin(mTOR) and AMP-activated protein kinase(AMPK) in the hypothalamus was seen. During the fasting period, there was an increase in expression of AMPK seen in 10 and 18 days, also mTOR reduction. Expression of NPY, AgRP, and POMC suffered the fasting effect only at 18 days. The effect of gastric distention and energy loads, there was increased expression of AMPK at 10 and 18 days, but expression of mTOR showed only at 18 days. There was increased NPY expression at 18 days, but not at 10 days, while AgRP increased its expression at both ages. At 10 days gene expression of CART increased and POMC as well as 10-18 days. Data demonstrated a simultaneous responsiveness to hypothalamic nutrient sensing also, controlling peptide food consumption even at an early age. The mature standard of control only observed at 18 days of life.

Maternal deprivation in the early versus late postnatal period differentially affects growth and stress-induced corticosterone responses in adolescent rats

Periodic maternal deprivation (MD) in the early postnatal period leads to permanently altered responsibility of the hypothalamus-pituitary-adrenocortical (HPA) axis to various types of stress. However, no reports appear to have described the effect of periodic MD under different conditions on growth of the developing rat and responsibility of the HPA axis to immobilization stress in adolescent rats. Furthermore, although body weight changes are known to affect stress responsibility, their relationship under periodic MD is not clear. The present study therefore used 4 different types of periodic MD: for 12 h/day from postnatal day (P)1 to P6 (12E group); for 3 h/day from P1 to P6 (3E group); for 12 h/day from P16 to P21 (12L group); and for 3 h/day from P16 to P21 (3L group). Mean body weights were less in the 3E and 12E groups than in the control group until at least 9 weeks old, although body weight gain in the 3L and 12L groups was only transiently affected. Stress-induced corticosterone levels in the 3E and 12E groups did not return to basal levels until at least 330 min after the termination of stress, while temporal variations of stress-induced corticosterone levels did not differ significantly between the 3L, 12L and control groups. Periodic MD in the first postnatal week affected growth of developing rats and responsibility of the HPA axis to immobilization stress in adolescent rats, and the extent of this modification was larger with MD for 12 h/day than with MD for 3 h/day. Conversely, periodic MD from P16 to P21 had little effect. Periodic MD in the postnatal period induces long-term effects on growth and stress responsibility of the HPA axis. Furthermore, a critical age of the pup at the time of MD exists as well as a critical length of MD for inducing these effects.

Differential effects of lipoprivation and food deprivation on chow and milk intake in 25- and 30-day-old rats

The effects of administration of mercaptoacetate (MA) and overnight food deprivation on intake of chow and milk diets were investigated in juvenile rats. In rats aged 25 or 30 days, administration of mercaptoacetate-stimulated intake of rat chow, while either suppressing intake or not affecting intake of milk diets. These effects were observed when each diet was presented individually, and when animals had both diets simultaneously. In contrast, overnight food deprivation led to enhanced intake of both diets, whether presented individually or available simultaneously. These results suggest that by 25 days of age, rats acquire an adult-like increase in food intake following lipoprivation by administration of MA. However, the effects of MA on intake in animals at these ages depends on the diet offered.

2-Mercaptoacetate does not stimulate chow intake in periweanling rats

In adult rats, administration of drugs that suppress oxidation of fatty acids, like mercaptoacetate (MA), produces increases in food intake. During development, the consequences of administration of MA are more varied. For example, in very young pups, intake of milk diets is unaffected by MA, while pups aged 12 to 15 days demonstrate increases in intake. However, in 18- and 21-day-old rats, milk intake is suppressed by administration of MA. Typically, the paradigms used to test rat pups differ significantly from those used to assess intake in adult rats. The present experiments were designed to examine whether 18-day-old pups tested with adultlike paradigms showed adultlike responses to administration of MA. In the first experiment, rat pups aged 18 days were injected with 0 or 68.4 mg/kg MA, then given 60-min tests while consuming either milk or chow diets that were novel, or to which they had previously been exposed. The results demonstrated that chow intake was not affected by administration of MA, but milk intake in experienced animals was suppressed by MA. Experiment 2 demonstrated that in contrast to administration of MA, 18-day-old pups deprived of food overnight showed increases in intake of chow and milk diets. In Experiment 3, when the effects of a range of doses of MA (22.8, 45.6, 68.4 and 91.2) on chow intake over a 4-h period were assessed, all doses of MA produced a significant suppression of chow intake in 18-day-old pups. Taken together, the data suggest that alterations in fatty acid oxidation produced by administration of MA do not stimulate chow intake in periweanling pups tested in an adultlike fashion.

Do metabolic signals stimulate intake in rat pups?

During early postnatal life, rat pups make a transition from suckling to food intake independent of the dam. Accompanying this transition is the requirement for pups to independently modulate their ingestive behavior. In adult animals, one set of signals known to modulate intake is generated by administration of agents that interfere with metabolism of glucose or fats (such as mercaptoacetate [MA] or 2-deoxyglucose [2-DG]). However, demonstrations of the effects of such agents in young rats have been less robust. Recent work in our lab has focused on examining the effects of MA and methyl palmoxirate (MP) on independent ingestion in pre- and periweaning rats. In rat pups between the ages of 12 and 15 days, latencies to initiate intake independent of the dam are typically longer relative to older or younger pups. However, the latency with which 12- and 15-day-old pups initiate independent ingestion is reduced following administration of MA. Further, MA produces physiological changes consistent with a change in the oxidation of fatty acids in 12- and 15-day-old pups, and similar physiological changes are produced during moderate periods of food deprivation in pups at the same ages. Thus, signals related to changes in the oxidation of fatty acids normally produced by moderate food deprivation in periweaning rats may provide a fundamental signal involved in the onset and modulation of intake independent of the dam.

Gastric emptying and control of ingestion in preweanling rat pups

In adult rats, the rate of gastric emptying is modulated by properties of the diet, including its caloric content and osmotic properties. In developing pups, there is little known about the modulation of gastric emptying, despite evidence that volume of gastric contents may play a significant role in modulating intake in young rats. The present experiments examined gastric emptying of oral infusions of corn oil emulsions or glucose solutions in pups aged 6 or 15 days of age and their effects on independent ingestion. The results demonstrated that pups as young as 6 days of age modulate the rate of gastric emptying in response to changes in the concentration of a corn oil or glucose diet. However, oral infusions of corn oil emulsions failed to produce differences in subsequent intake of a milk diet, while oral infusions of a glucose diet did suppress subsequent intake. Taken together, the results support different ontogenetic courses for the development of mechanisms modulating gastric emptying of lipid versus carbohydrate diets, and suggest that gastric fill plays a limited role in modulation of intake in young pups.

Metabolic and behavioral responses in pre-weanling rats following alteration of maternal diet

In rat pups, blockade of fatty acid oxidation by administration of 2-mercaptoacetate (MA) produces an increase in independent ingestion by 12 days of age. In contrast, administration of methyl palmoxirate (MP) fails to increase intake or to alter oxidation of fatty acids in young rats due to the high proportion of medium chain triglycerides (MCT) in rat milk. In the present experiments, the composition of rat milk was altered by placing dams on a high fat (HF) diet to examine the development of ingestive responding in rat pups following administration of MP. Following delivery of MP (0.5--10 mg/kg), pups were placed in a cage inside an incubator for 1, 3, or 6 h, and then received an intake test consuming a commercial half-and-half milk diet from the floor of test containers. Blood was collected from additional groups of pups for measurement of beta-hydroxybutyrate (beta HBA) and glucose levels. The results demonstrated that administration of MP produced significant reductions in beta HBA levels after 3 h in 12- and 15-day-old pups, but behavioral responses were noted only in pups aged 15 days. Similar results were obtained following administration of MA to pups reared by dams on HF diets; physiological responses were observed at 12 and 15 days of age, but behavioral responses were not observed after administration of MA until 15 days of age. Taken together, these results suggest that (1) changes in fatty acid oxidation may represent an early metabolic signal that can influence intake in rat pups and (2) alteration of the dam's diet produces physiological and behavioral changes in the pups.

Brain oxytocin receptor antagonism disinhibits sodium appetite in preweanling rats

Previous studies have shown that preweanling rats do not express an endogenous sodium appetite until postnatal day 12. The present studies tested the hypothesis that prior to 12 days of age sodium appetite, induced by either central administration of angiotensin II (AngII) or adrenalectomy, is inhibited by endogenous oxytocin (OT). After 9- or 10-day old animals were given a central injection of either an OT receptor antagonist or vehicle, they were infused intraorally with 4% sodium chloride which the animals could either swallow or reject. Intake was measured as the increase from initial body weight. There was very little sodium consumption by vehicle-injected animals that received sham surgery or adrenalectomy; however, the OT receptor antagonist significantly elevated sodium consumption in adrenalectomized animals. The OT antagonist also potentiated sodium intake after AngII pretreatment. These results suggest that the neurochemical circuits necessary for the expression of sodium appetite are present and functional as early as postnatal day 9; however, until 12 days of age this behavior is suppressed by endogenous OT.

Effects of physiological state on oral habituation in developing rats: cellular and extracellular dehydration

Hydrational state has been demonstrated to influence intake of various solutions in young rat pups. For instance, both cellular and extracellular dehydration produce an enhancement of intake in pups tested at 6 days of age. However, the behavioral mechanisms that result in increased intake following manipulations of hydrational state have been less extensively studied. The impact of hydrational state on behavioral responsiveness in young rat pups was examined by assessing the pattern of responding to a series of repeated oral infusions of diet. Pups were tested at 6, 12, or 18 days of age following either acute cellular dehydration produced by injection of 1 M NaCl or acute extracellular dehydration produced by injection of 10% polyethylene glycol (PEG). Oral responsiveness to a series of 30 brief infusions of one of four taste solutions (water, 10% sucrose, 0.135 M NaCl, or 1 M NaCl) was measured. Each infusion lasted 3 s and there was 1 min between infusions. The pattern of oral responding to solutions was affected by the developmental age of the pup, the hydrational state of the pup, and the solution offered, with the largest effects of dehydration observed in the youngest animals. In all conditions except one, pups habituated to repeated infusions. The exception was the failure of extracellularly dehydrated 6-day-old pups to display habituation to oral infusions of sucrose. These results suggest that, although intake is enhanced by both cellular and extracellular dehydration in very young pups, the behavioral changes responsible for the enhancement of intake after cellular dehydration are different from the behavioral changes resulting from extracellular dehydration. This dissociation of behavioral effects of dehydration in young pups demonstrates that intake measures alone may obscure subtle differences in behavior and argues for the utility of dissection of behavioral components in understanding the neural and physiological control of behavior.