Early life experience shapes the functional organization of stress-responsive visceral circuits

Emotions are closely tied to changes in autonomic (i.e., visceral motor) function, and interoceptive sensory feedback from body to brain exerts powerful modulatory control over motivation, affect, and stress responsiveness. This manuscript reviews evidence that early life experience can shape the structure and function of central visceral circuits that underlie behavioral and physiological responses to emotive and stressful events. The review begins with a general discussion of descending autonomic and ascending visceral sensory pathways within the brain, and then summarizes what is known about the postnatal development of these central visceral circuits in rats. Evidence is then presented to support the view that early life experience, particularly maternal care, can modify the developmental assembly and structure of these circuits in a way that impacts later stress responsiveness and emotional behavior. The review concludes by presenting a working hypothesis that endogenous cholecystokinin signaling and subsequent recruitment of gastric vagal sensory inputs to the caudal brainstem may be an important mechanism by which maternal care influences visceral circuit development in rat pups. Early life experience may contribute to meaningful individual differences in emotionality and stress responsiveness by shaping the postnatal developmental trajectory of central visceral circuits.

Ontogeny of hypothalamic-hindbrain feeding control circuits

Ingestive behavior is a complex product of distributed central control systems that respond to a diverse array of internal and external sensory stimuli. Relatively little is known regarding the pathways and mechanisms by which relevant signals are conveyed to the neural circuits that ultimately control ingestive motor output. This report summarizes findings regarding the postnatal development of descending hypothalamic inputs to the hindbrain dorsal vagal complex (DVC). Evidence accumulated primarily in rats indicates that descending neural projections from the hypothalamus to the DVC are both structurally and functionally immature at birth. The progressive postnatal maturation of these projections occurs in parallel with newly emerging physiological and behavioral responsiveness to treatments and stimuli that affect food intake in adults. Thus, the postnatal emergence of new feeding controls may reflect the emerging access of these controls to DVC neural circuits.

Taste differentiation in the context of suckling and independent, adultlike ingestive behavior

The present study compared intake of sweet (saccharin), bitter (quinine), and neutral (water) tastants available either in the context of suckling behavior through a surrogate nipple or independent adultlike feeding through an intraoral cheek cannula in 3-hr-old newborn rats lacking any suckling experience and 24-hr-old rats with regular experience with the dam's nipple. The new technique of online monitoring of fluid flow was applied for assessment of the temporal patterns of ingestion. Newborn and 1-day-old rats tested in the context of suckling behavior showed extremely low intake of quinine, moderate intake of water, and high intake of saccharin. In the same way, they demonstrated low intake of quinine and high intake of saccharin in the context of independent feeding, but intake of water was also high and comparable to that of saccharin. Suckling rats attained higher efficacy of fluid extraction from nipple than pups drinking from cannula. The differential responsiveness to quinine, saccharin, and water in suckling rats was also manifested through attachment behavior, with pups spending less time on the nipple providing quinine and more time on the nipple with saccharin than on the nipple providing water. These results suggest that neonates show taste differentiation as early as 3 hr after birth, and that this taste differentiation is more pronounced in the context of suckling behavior than in the context of adultlike, independent ingestion.

Motivating operations in appetite research

Appetite research frequently employs principles derived from behaviour analysis. However, it has yet to utilise the more recent theoretical advances in this field. This paper describes the concept of the motivating operation (MO)--a behaviour analytic formulation of motivation. An MO is an environmental event that (a) establishes or abolishes the reinforcing or punishing effect of another event and (b) evokes or abates behaviours associated with that event. The paper describes both unconditioned and conditioned MOs and the ways in which they may help account for a variety of eating behaviours. It then goes on to highlight the main ways in which the MO account differs from other theories of motivation employed in appetite research. These relate to (1) the ways in which they account for non-regulatory feeding, (2) the extent to which they address cognitive variables and (3) their underlying philosophical assumptions and subsequent relation to intervention.

Postnatal development of hypothalamic inputs to the dorsal vagal complex in rats

The hypothalamus is critically involved in energy homeostasis and is an appropriate focus for research investigating the central neural underpinnings of obesity, anorexia and normal food intake. However, little is known regarding pathways and mechanisms that convey relevant hypothalamic signals to the brainstem circuits that ultimately control ingestive behavior. This brief review highlights work investigating the postnatal development of hypothalamic inputs to the hindbrain dorsal vagal complex (DVC). Research findings indicate that these inputs are both structurally and functionally immature in newborn rats. The progressive postnatal maturation of descending projections to the DVC occurs in concert with newly emerging physiological and behavioral responses to osmotic dehydration, which inhibits gastric emptying and food intake in adult animals but not in neonates. The postnatal emergence of other intake controls might also reflect progressive engagement of DVC neural circuits, whose intrinsic components and output pathways are envisioned as being critical for initiating and terminating ingestive behavior.

Effects of prior experience with dehydration and water on the time course of dehydration-induced drinking in weanling rats

Although cellular dehydration increases oral responding and swallowing of orally infused water in rats as young as 2 days old, it is not until well after the time of weaning that dehydration stimulates immediate water-seeking and initiation of drinking in situations where the water source must be approached voluntarily. Recent work has shown that the goal-directed appetitive sequence for drinking-orienting, approaching, and initiating contact with water-matures much later than the more precocial oral licking and swallowing behaviors, and normally comes to be elicited by dehydration only after post-weaning experience with dry food. In the current experiments we evaluate some critical features of post-weaning experience with dehydration and drinking, and find that prior experience with initiating drinking while dehydrated, but not experience with dehydration nor water per se, alters the time course of water intake during a subsequent hydrational challenge. The effects of experience are manifested as an increased proportion of water consumed in the early portion of the test, rather than a general increase in total consumption. These findings are consistent with the interpretation that prior experience is necessary for the coordination of water-oriented appetitive behaviors that lead to the initiation and maintenance of drinking bouts, and provide further evidence for an associative learning account of the acquisition of dehydration-induced drinking.

The acquisition of an appetite

Unlike older animals, weanling-age rats do not seek water to drink when they are dehydrated, despite the fact that a physiological sensitivity to dehydration is present very soon after birth. We demonstrate here that the appetitive behaviors needed to approach and obtain water become linked to dehydration only as a result of specific postnatal learning experience. Preventing early experience with dehydration retards the developmental emergence of dehydration-induced, water-oriented behavior in young rats. But a single pairing of water with dehydration can establish an appetitive response. These findings reveal a critical role of early learning in the development of goal-oriented behavior. Such a learning process is potentially characteristic of other behavioral systems, from the most basic appetites to complex motives.

Ontogeny of hypertonic preabsorptive inhibitory control of intake in neonatal rats

The ontogenetic development of postingestive inhibitory control of ingestion by the osmotic load of a preload was examined in rats. On postnatal days 6 (P6) and 12 (P12), pups were deprived for either 6 or 24 h. Gastric preloads (5% body wt) of water, mannitol (a sugar alcohol that is not absorbed) in six concentrations [from 0.125 M (hypotonic) to 1.0 M (hypertonic)], or sham preloads were administered 5 min before a 30-min intake test. Compared with sham treatment, isotonic mannitol (0.25 M), a probe of volumetric control, significantly reduced intake on P12, but not on P6. Compared with isotonic mannitol, the three highest hypertonic concentrations (0.5, 0.66, and 1.0 M) significantly decreased intake on P12, at both levels of deprivation. On P6, 0.66 and 1.0 M mannitol reduced intake after 24 h, but not after 6 h, of deprivation. Thus, on P6, the hypertonic control was detectable only after prolonged deprivation and the volumetric control was not present. On P12, both controls were observed and the hypertonic control was more potent than on P6.

The postnatal emergence of dehydration anorexia in rats is temporally associated with the emergence of dehydration-induced inhibition of gastric emptying

Osmotic dehydration produced by systemic hypertonic NaCl (HS) inhibits gastric motility and emptying and also inhibits feeding in adult rats. Conversely, in neonatal rats, dehydration does not inhibit feeding. The present study examined whether the postnatal emergence of dehydration anorexia is temporally associated with the emergence of dehydration-induced inhibition of gastric emptying. Rat pups 4 to 19 days old were injected subcutaneously with HS (0.75 M NaCl; 200 microL/10 g body weight). Control rats were injected with isotonic saline (0.15 M NaCl). Thirty minutes later, rats were given access to milk that could be lapped from paper towels on the floor of a warm testing chamber. Other HS-treated and control rats were given an intragastric load of 0.15 M NaCl (2% body weight) and then killed after 30 min to determine how much of the load had emptied from the stomach. Consistent with previous reports, HS-treated rats consumed significantly more milk than control rats from postnatal Day 4 (P4) through P11 but consumed significantly less milk than controls at P19. HS treatment did not affect gastric emptying of 0.15 M NaCl at P4 or P11. Conversely, HS treatment significantly inhibited gastric emptying at P19. These findings suggest that the hypophagic effects of dehydration develop in tandem with inhibitory effects on gastric motility and are consistent with the view that the full complement of mature homeostatic responses to plasma hyperosmolality requires coordinated activation of forebrain and hindbrain neural circuits that are only partially formed in neonatal rats.

Central c-Fos expression in neonatal and adult rats after subcutaneous injection of hypertonic saline

Centrally-mediated responses to plasma hyperosmolality include compensatory drinking and pituitary secretion of vasopressin and oxytocin in both adult and neonatal rats. However, the anorexia that is produced by plasma hyperosmolality in adult rats is not evident in neonates, perhaps due to functional immaturity of osmoresponsive hindbrain circuits. To examine this possibility, the present study compared treatment-induced brain expression of the immediate-early gene product c-Fos as a marker of neural activation in adult and two-day-old rats after subcutaneous injection of 2 M NaCl (0.1 ml/10 g body weight). This treatment produced marked hypernatremia in adult and two-day-old rats without altering plasma volume. Several brain regions (including components of the lamina terminalis, the paraventricular and supraoptic nuclei of the hypothalamus, and the area postrema) were activated to express c-Fos similarly in adult and two-day-old rats after 2 M NaCl injection, consistent with previous reports implicating a subset of these regions in osmotically-stimulated drinking and neurohypophyseal secretion. In contrast, other areas of the brain that were activated to express c-Fos in adult rats after 2 M NaCl injection were not activated in neonates: these areas included the central nucleus of the amygdala, the parabrachial nucleus and catecholamine cell groups within the caudal medulla. This study demonstrates that certain brain regions that are osmoresponsive in adult rats (as defined by induced c-Fos expression) are not osmoresponsive in two-day-old rats. When considered in the context of known differences between the osmoregulatory capacities of adult and neonatal rats, our results are consistent with the idea that osmoresponsive forebrain centres are primarily involved in osmotically-stimulated compensatory drinking and neurohypophyseal secretion, whereas osmoresponsive regions of the hindbrain are important for concomitant inhibition of feeding and gastric emptying.

Characteristics of glucose and maltose preloads that inhibit feeding in 12-day-old rats

Nonvolumetric inhibitory control of food intake during independent ingestion was studied in rats on postnatal day 12. Pups received either sham intubation or equivolumetric (5% BW) preloads of 20% (w/v) glucose, 20% maltose, 20% 2-deoxy-D-glucose (2-DG), 0.9% NaCl, 200 mg soybean trypsin-inhibitor (SBTI) or distilled water, 5 min prior to 30-min access to a milk diet spread on the floor of a beaker. To investigate if endogenous cholecystokinin mediated any of the inhibitory effects of the preloads on intake, pups were injected IP with 1 mg/kg devazepide, a specific CCK(A) receptor antagonist, or with vehicle 30 min prior to the intake test. All preloads reduced intake (measured by percent body weight gain) compared to sham intubation. Glucose (20%) reduced intake significantly more than 0.9% saline, but not more than the preload of 20% 2-DG. This suggests that the effect of glucose can be accounted for by its preabsorptive osmotic properties because 2-DG is not actively transported or metabolized. The inhibitory effect of 20% maltose may also be due to its osmotic load, but these experiments did not provide clear evidence for this. Cholecystokinin apparently did not mediate the effect of any of the preloads except SBTI, because devazepide only reduced the inhibition produced by a preload of SBTI. These results provide further evidence that hypertonic stimuli in the stomach or small intestine provide inhibitory control of food intake by postnatal day 12.

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.

The selective angiotensin AT1 receptor antagonist LR-B/081 potently inhibits drinking induced by central injection of angiotensin II in rats

LR-B/081, methyl-2-[[4-butyl-2-methyl-6-oxo-5-[[2'-(1H-tetrazol-5-yl) [1,1'-biphenyl]-4-yl] methyl]-1(6H)-pyrimidinyl] methyl]-3-thiophenecarboxylate, is a recently developed nonpeptide antagonist selective for angiotensin AT1 receptors. The drug has been reported to be an insurmountable angiotensin AT1 receptor antagonist endowed with long-lasting antihypertensive activity. A large body of evidence indicates that angiotensin AT1 receptors mediate the dipsogenic action of angiotensin II in the central nervous system. The present study evaluated the ability of LR-B/081, in comparison with losartan and with its active metabolite EXP3174, to inhibit drinking induced by central injection of angiotensin II in water-sated rats. LR-B/081, in the dose range of 10-1000 pmol/rat, dose dependently inhibited the drinking response to angiotensin II, 10 pmol/rat. The ID50 of LR-B/081 was 25.9 pmol/rat, while that of losartan and EXP3174 was 357 and 3.9 pmol/rat, respectively. Therefore LR-B/081 was about 7 times less potent than EXP3174, but about 14 times more potent than the parent molecule losartan. LR-B/081 altered neither carbachol-induced water intake, nor 15% fat milk intake in rats, suggesting that its effect on angiotensin II-induced drinking is a behaviourally selective effect. These findings show that LR-B/081 potently inhibits central angiotensin AT1 receptors involved in behaviourally selective effect. These findings show that LR-B/081 potently inhibits central angiotensin AT1 receptors involved in the control of body fluid homeostasis and suggest that this drug might be an interesting pharmacological tool to further investigate the role of the central renin-angiotensin system in physiological or pathological conditions.

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.

Salt appetite consequent on sodium depletion in the suckling rat pup

The ontogeny of the behavioral ability to compensate for sodium deficit was studied in the rat. The experiments showed that: 1) Before weaning age, sodium-depleted pups will increase their avidity for 3% NaCl solution; 2) the ability to select and drink a salt solution in response to a sodium deficit continues to evolve between 17-24 days of age, and that pups at these ages will modify their intake of salt and water as do adult rats when rectifying plasma osmolality; 3) The increased appetite for sodium is evident even when depleted preweanlings are dehydrated and provided with solid NaCl tablets to lick, showing that sodium appetite and hydrational status are already dissociated at this age; and finally, 4) sodium depletion first induces an increase in intake of orally infused 3% NaCl solution in 12-day-old pups. The picture of the development of salt appetite in the suckling rat that these findings present is of a precocious competence to meet a challenge to sodium homeostasis. In this respect salt appetite emerges in parallel to the other ingestive behaviors.

The early presence of food-oriented appetitive behavior in developing rats

The appetitive behavior of 3- to 6-day-old rat pups was studied by testing their ability to direct their ingestive behavior to a restricted food source. We found that, from 3 days of age, pups were able to feed efficiently from such a source. More specifically, pups that were deprived of nutrition but not of maternal care as well as pups that were dehydrated ingested significantly more than nondeprived animals, and did so whether liquid diet was spread over the entire floor surface beneath them or restricted to a fraction of the floor surface. However, pups that had been nutritionally and maternally deprived were not able to direct their feeding. The general locomotor activation of pups in this latter group appeared to interfere with their ability to direct their behavior to the restricted source. These results indicate that from early ages, developing rats possess the appetitive competence to guide their behavior and suggest that previous findings of poorly directed behavior were a confound of the behavioral activation shown by pups tested in a state of maternal deprivation.

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

The physiological stimulus for deprivation-enhanced ingestion was studied in developing rats. During an overnight deprivation period, continuous gastric infusions of isotonic saline or milk were made to 6- and 15-day-old rat pups in order to preferentially maintain hydrational or hydrational and nutritional status, respectively. Pups' ingestion was then studied in oral-infusion tests. In 6-day-old pups that received either milk or saline infusions, ingestion was depressed relative to intake in pups that were simply deprived. But in 15-day-old pups, only milk infusions reduced intake. These findings suggest that the increased ingestion stimulated by deprivation in pups less than a week of age results primarily from dehydration, and thus that nutrient-related feeding does not emerge until later in development.

Infant rats depleted of brain dopamine as neonates exhibit normal independent ingestion

Weanling or adult rats that have sustained near-total depletions of striatal dopamine (DA) on postnatal Day 3 do not exhibit the severe ingestive deficits seen in comparably depleted adults. The present experiments demonstrated that these animals are capable of ingesting independently, via an intraoral cannula, as early as three days after the depletion. Both activational and ingestive responses to maternal deprivation and intracellular dehydration were virtually identical to the responses of control pups. However, these responses may not be entirely dopaminergically mediated at Day 6 since administration of haloperidol failed to attenuate these behaviors in normal pups. When tested on Day 12, DA-depleted pups continued to exhibit normal ingestive and activational behaviors, despite the fact that haloperidol now suppressed these behaviors in both groups of 12-day-old pups. These findings demonstrate that there is a developmental progression of dopaminergic involvement in the control of independent ingestion and the associated activational responses, yet a near-total depletion of striatal DA is not sufficient to impair the expression of these behaviors.

The ontogeny of opioid receptors mediating opiate-induced feeding in rats

Acute administration of naloxone to preweanling rats does not attenuate independent ingestion of milk until 14 days of age suggesting that the full expression of an endogenous opioid system(s), regulating feeding rats, is not complete prior to this age. The present study was undertaken to examine the functional ontogeny of opioid receptors mediating opiate-induced feeding in rats. Rat pups, satiated with milk, were given intraperitoneal injections of the opiate receptor agonist, morphine, and were allowed free access to milk. Morphine stimulated the intake of milk at 3, 5, 7, 14 and 21 days of age, within 2 hr of injection. A time-course analysis in 7-day-old pups showed greater enhancement of intake between hours 2 and 4, than between hours 0 and 2, for large doses of morphine (0.3 and 1.0 mg/kg) suggesting that morphine-induced behavioral depression, which was observed early in the test session, confounded intake at earlier hours. Administration of the opiate receptor antagonist, naltrexone, produced no effect on intake of its own, but blocked the stimulation of intake by morphine in 5-day-old pups confirming that the effect of morphine on the intake of milk was mediated by opioid receptors. Thus, while a functional endogenous opioid system(s), regulating feeding in rats, is not fully mature until 14 days postpartum, the present results suggest that opioid receptors mediating feeding are functional very early in the postnatal development of the rat.

The ontogenesis of lithium-induced effects on suckling: inhibition and facilitation

The ontogenesis of the effect of lithium on suckling behavior was assessed by administering lithium carbonate directly and acutely to 15-, 20-, 30-, and 35-day-old rat pups. Lithium significantly interfered with nipple attachment in 15-day-old rat pups in a dose-dependent pattern, but it facilitated attachment at some doses (40, 60, 80 mg/kg) in weanling-age rat pups. Furthermore, lithium pretreatment reversed quipazine-induced interference of attachment in weanling-age rats. These effects are similar to those previously reported with serotonergic antagonists, suggesting a similar mechanism, perhaps via the inositol phosphate second messenger system.

Ontogeny of renin-induced salt appetite in the rat pup

Intracerebroventricular injections of renin in suckling rat pups increased intake of NaCl solutions when they were orally infused 5 hr after injection. The appetite for saline solution was evident in pups as young as 3 days, was greater in females, and was specific insofar as intake of milk, either by suckling or by oral infusion, was not affected. Three-day-old pups increased intake only to 12% NaCl, the acceptable concentration of NaCl becoming lower in older pups. These results suggest, first, that, as is true for feeding and drinking, the brain mechanism for salt appetite is competent for expression of the behavior in the very young rat pup, and second, that its angiotensinergic neural substrate is distinct from that which mediates the dipsogenic effect of the hormone.

Suppression of salt intake in the rat by neurokinin A: comparison with the effect of kassinin

The present study investigates the effect of the mammalian tachykinin neurokinin A on salt intake in the rat. Intracerebroventricular injection of neurokinin A inhibited salt intake elicited by sodium depletion, by subchronic deoxycorticosterone treatment and by adrenalectomy. It also inhibited the need-free salt intake of female rats that had been previously depleted of sodium. Since different brain mechanisms elicit salt intake in these experimental models, it is concluded that neurokinin A exerts a general antinatriorexic effect. Apparently, its inhibitory effect on salt intake is not due to malaise or competing behaviors, as shown by the fact that the doses of neurokinin A which suppress salt intake do not suppress milk intake. In comparison to the amphibian tachykinin kassinin, neurokinin A possesses a similar spectrum of antinatriorexic activities, but is markedly less potent and less effective in all the experimental models investigated. These findings suggest that activation of neurokinin A receptors cannot solely account for the potent antinatriorexic effect of kassinin and of other nonmammalian tachykinins.

Drinking behavior and motor function in rat pups depleted of brain dopamine during development

The ability of rat pups depleted of brain dopamine (DA) at either 3 or 15 days of age to increase fluid intake in response to intracellular dehydration was studied. Despite near-total depletions of striatal DA, animals depleted at either age ingested normal amounts of fluid even as soon as 3-7 days after incurring the brain damage. The effects of DA receptor blockade on ingestion and motor function were also studied. Haloperidol had markedly different effects as a function of the age at which the depletions were sustained. Weanlings that were depleted of DA at 3 days of age failed to exhibit the drug-induced adipsia, akinesia, and catalepsy seen in controls and animals that were depleted at 15 days of age. These findings suggest that the DA depletions were performed at different periods of brain organization. The resultant neural controls of ingestion and motor function are qualitatively different in the two groups of depleted animals. Rats depleted at 3 days of age utilize nondopaminergic mechanisms, whereas animals lesioned at 15 days of age continue to rely upon residual DA neurons for both behaviors.

Histamine-elicited drinking in weanling and adult rats

A total of 260 male and female adult (60-70 days of age) and weanling (22-25 days of age) Sprague-Dawley derived rats were used in these experiments. Subcutaneous administration of histamine (HA) elicited drinking in a dose-dependent manner for both ages tested, although the threshold dose varied with age. A dose of 5.0 mg/kg HA elicited significant increases in water intake for adults, whereas for weanlings a dose of 20 mg/kg HA was necessary. Adult rats exhibited decreased latency to drink after all doses of HA tested, whereas for weanlings, decreased latency was evident only after doses of HA sufficient to elicit increases in water intake. Combined antagonism of H1 and H2 receptors for HA, using dexbrompheniramine and cimetidine, respectively, inhibited HA-elicited drinking in adults and weanlings. Further investigation of the ontogeny of histamine- and food-related drinking may provide a useful approach to examine the physiological mechanisms underlying fluid consumption in adult animals and as they are gradually elaborated during ontogeny.

Thirst-induced anorexias and the ontogeny of thirst in the rat

In previous work (Leshem, M., Boggan, B., and Epstein, A.N. (1988). The ontogeny of drinking evoked by activation of brain angiotensin in the rat pup. Dev. Psychobiol. Vol.21, pp. 63-75) we showed that thirst elicited by activation of the brain's renin-angiotensin system in the suckling becomes specific to water after 16 days of age. However, in the suckling, we did not find the anorexia that reportedly accompanies angiotensin-induced thirst in the adult. This suggests the existence of a further stage in the ontogeny of thirst. Therefore, the present study pursued the ontogeny of thirst and its effects on milk intake through prepubescence into adulthood. Experiment 1 revealed that intracranial renin does not cause an anorexia to milk in prepubescent or adult rats. Experiment 2 showed that the absence of anorexia is true of thirst induced by renin but not by cellular dehydration, although both dipsogens suppressed milk intake when rats also had water available. Experiment 3 confirmed that the preweanling shows anorexia to solid food, as does the adult. Together with other work, these findings suggest that the ontogeny of the thirsts aroused by renin or intracellular dehydration is complete before weaning.

Development of chorda tympani nerve taste responses in the hamster

To determine whether changes in salt and sugar responses occur during development in the hamster, multifiber responses were recorded from the chorda tympani nerve while stimulating the anterior tongue of preweanling, early postweanling, and adult hamsters. Gustatory stimuli included 0.1 and 0.5 M solutions of NH4Cl, NaCl, LiCl, and KCl, and concentration series (0.01-1.0 M) of glucose, fructose, sucrose, maltose, lactose, and (0.0005-0.01 M) saccharin. Dramatic alterations in hamster peripheral gustatory sensitivities occurred with age, with the direction and magnitude of change dependent on the specific stimulus. Response magnitudes to 0.1 M solutions of NaCl and LiCl decreased with age compared to the NH4Cl response, whereas responses to all other salt stimuli remained constant during development. Responses to all sugars and saccharin compared to the NH4Cl response increased during development across a large concentration range; however, the age at which mature responses were achieved depended on the specific "sweet" stimulus. Whereas these findings demonstrate that the hamster peripheral gustatory system is dynamic during postnatal development, the hamster has a unique developmental pattern of salt taste development compared to other species. Specifically, the effectiveness of NaCl and LiCl decrease during development compared to NH4Cl in the hamster, but increase dramatically in the rat and sheep. Thus, the developmental patterns are opposite in direction for the hamster compared to the rat and sheep and may relate to the environmental pressures imposed upon each species.

The ontogeny of drinking evoked by activation of brain angiotensin in the rat pup

Renin (1 ng) was injected into the 3rd ventricle of the brain of rat pups at various ages, and their ingestion was measured by weighing them either after 40 min of oral infusion of water or milk while they were away from their dam (off-dam), or after 40 min of suckling from their dams (on-dam). Beginning at 3-5 days of age, renin increased ingestion of milk and water off-dam. After 15 days of age, milk ingestion off-dam was no longer increased by renin, but intake of water continued to be evoked. In contrast, renin did not increase intake by suckling at any age. These findings reveal that the adult characteristics of the dipsogenic action of the renin-angiotensin system in the brain emerge at 15 days, at which age the increased intake becomes entirely specific for water. This finding confirms the precocity of the neural controls of drinking in the rat and shows that, like the controls of independent feeding, they are dissociated from those of suckling. It adds support to the idea that the neonatal mammalian brain contains separate neurological systems for suckling and for independent ingestion.

The ontogeny of the antidipsogenic effect of eledoisin and physalaemin in the rat

The ontogeny of the antidipsogenic effect of the tachykinins eledoisin and physalaemin was studied in 1- to 12-day-old Wistar rats. Both peptides inhibited drinking evoked by ICV angiotensin II, cell-dehydration or fluid deprivation. The effect of eledoisin appeared earlier than that of physalaemin (third v. sixth day) and was evoked by lower doses (10-100 ng/rat vs 330-1000 ng rat). The two tachykinins also inhibited milk intake, but this effect occurred only in the earliest days of neonatal life. The results confirm the specificity of the antitipsogenic effect of eledoisin and physalaemin and give further support to the hypothesis that brain tachykinins play a physiological role in the control of fluid intake.

Sapid savvy in sucklings: the effect of quinine hydrochloride on intraoral negative pressure and intake by 11-13-day-old rat pups

Three experiments describe the consummatory behavior of 11-13-day-old rat pups during and following experience with a model aversive taste, quinine hydrochloride. Pups were observed while away from the dam and while suckling. Results show that pups actively reject quinine adulterated solutions in both situations. They do so by spitting the solution from the mouth when away from the nipple and by leaving the nipple and/or decreasing their sucking effort when with the dam.

Ontogeny of glucose inhibition of independent ingestion in preweanling rats

Rat pups that have been maternally and nutritionally deprived will vigorously ingest diet infused directly into the mouth. The development of nutritive controls in this form of ingestion was examined by administering nutritive and non-nutritive gastric preloads to 6- and 15-day-old pups. In 6 day-old pups, nutritive gastric preloads (0.6 M glucose in distilled H2O or saline) and vehicle preloads were followed by similar intakes; only the change in hydrational state caused by distilled H2O loads appeared to affect intake. By 15 days of age, intake following nutritive preloads was less than intake following non-nutritive preloads. Also, at 15 days, stomach volume at the termination of intake was less following nutritive preloads. In a separate experiment with 6-day-old pups, gastric preloads of an alternative energy source, the ketone beta-hydroxybutyrate, also failed to inhibit intake when given at a dose that did not cause excessive gastric distension. These results indicate that a nutritive control of intake termination in rats is not present at 6 days of age but develops by 15 days of age.

The ontogeny of independent ingestion in mice: or, why won't infant mice feed?

Unlike infant rats, which show deprivation-related ingestion in several different test situations, infant mice appeared to be relatively unwilling to feed independently of suckling until 12 days of age. We tested mouse pups that were deprived (of food, water, suckling, and maternal care) for 1, 7, or 24 hr in ingestive tests in which a milk diet was spread on the floor of their test container (Experiment 1). Pups at 3, 6, and 9 days of age consumed small amounts of the diet and showed little increase in intake when deprivation was increased. In contrast (and like rat pups of all ages), mouse pups 12 and 15 days of age actively ingested the diet and increased their intake with increased deprivation. Six-day-old mouse pups were similarly unwilling to ingest a 5% sucrose solution, though 12-day-old pups showed deprivation-related intake (Experiment 2). Cellular dehydration (produced by hypertonic saline injection), a potent stimulus for ingestion in infant rats, did not stimulate ingestion in mice younger than 12 days of age (Experiment 3). Finally, when ingestion was tested with diet infusions made through oral cannulas, mouse pups at 6 and 9 days of age showed only a slight increase in intake with increased deprivation. However, by 12 days of age, pups' ingestion increased markedly with deprivation (Experiment 4). Thus, mouse pups seem to be very different from rat pups with respect to the early existence of ingestive systems. The neural substrates for the ingestive responses that subserve independent ingestion are only minimally present in infant mice or are somehow inhibited.

The ontogeny of salt preference in rats

Many mammals eat salt irrespective of need. This behavior, called salt preference or appetite, is studied primarily in adults. Little is known about its ontogeny. In these experiments, 3-18-day-old rat pups were offered saline, quinine, or ammonium chloride solutions by infusion through an anterior oral catheter, and intake was measured. At 6-18 days, pups showed the inverted U-shaped preference-aversion curve for NaCl that is characteristic of adult rats. Thus, rats express a preference for salt at a very early age. However, the curves were broader than the typical adult curve and were shifted along the concentration gradient in an age-related fashion. Consumption of quinine and ammonium chloride showed similar age-related changes. These changes may reflect the postnatal timing of the development of the rat gustatory system.

Suppression of drinking but not feeding by central eledoisin and physalaemin in the rat

The tachykinins, eledoisin and physalaemin, given by intracerebroventricular (i.c.v.) injection have been shown to be potent antidipsogenic agents in rats. To evaluate their selectivity of action on rat ingestive behaviors, we compared their effects following i.c.v. injection on the intake of water, of milk containing 3.5 or 15% fat, and of solid food. The two tachykinins inhibited water intake induced by i.c.v. angiotensin II or by cellular dehydration, but did not reduce the intake of 15% fat milk or of solid food. The intake of 3.5% fat milk was inhibited only by the highest dose (1000 ng/rat) of eledoisin which also increased grooming and locomotion. The present findings suggest that in adult rats central eledoisin and physalaemin exert a selective suppressive effect on drinking behavior without affecting feeding.

What we know and don't know about the development of independent ingestion in rats

Because suckling behavior differs in many ways from later ingestive behavior, the development of feeding and drinking in rats is best studied apart from the normal suckling situation. Newborn rat pups, separated from their mothers, will actively ingest diet infused into their mouths or spread on the floor beneath them. Such "independent" ingestion resembles the ingestive behavior of adult animals, but it also undergoes developmental changes in organization and control during the pre- and post-weaning periods: When young, deprived pups are fed, they show generalized, non-directed behavioral excitement; but with increasing age, this generalized responding matures into directed and focused ingestive activity. Early independent ingestion depends on a warm test environment; but with development, other familiar environmental and social cues come to influence responding. The internal controls of ingestion also change. Only gastric distension and hydrational status seem to be involved in controlling intake volume during early ingestion, with other ingestive controls emerging later in development. Thus ingestion, independent of suckling from the mother, is a system undergoing revealing developmental changes. These changes offer opportunities for studying ingestion, its controls, and its neural basis at its simplest organizational stage in the newborn, and at higher levels of complexity as maturation adds new components to the feeding system.

Appetitive conditioning in neonatal rats: conditioned ingestive responding to stimuli paired with oral infusions of milk

Components of rat pups' ingestive responses to orally infused milk came to be elicited by a novel odor conditioned stimulus (cedar) that had been repeatedly paired with milk infusions (Experiment I). Pups responded specifically to one odor, and they did not generalize their conditioned responding to either another odor or an unscented airstream (Experiment II). Ingestive responses could also be conditioned to a vibrotactile CS paired with milk, although levels of conditioned responding were lower than were obtained with an odor CS (Experiment III). Pups' internal state determined the effectiveness of training, in that pups that were removed from their dam for 24 hr showed reliable conditioned responding, while nondeprived pups and dehydrated pups did not (Experiment IV). Finally, pups showed retention of conditioned responding for at least several days after training (Experiment V).

Changes in appetitive behavior in weanling-age rats: transitions from suckling to feeding behavior

To help identify determinants of rat appetitive behavior during the weanling period, rat pups 17-32 days of age were studied in a Y-maze. One arm of the maze provided pups with the opportunity to suckle a lactating or nonlactating anesthetized female. The other arm always contained a familiar food, either liquid diet or ground laboratory chow. In some experiments the dam was separated from the food compartment by a thin gauze screen. In other tests maternal contact could be maintained in the feeding goal but suckling in that compartment was prevented by nipple involution. Age was the major determinant of choice, with more older animals choosing the food arm. Availability of maternal contact in the feeding compartment increased the percentage of rats that chose to feed by about 20% at all ages studied. Food quality, but not quantity, affected choice at each age, as did lactational status. Prior food, water, and maternal deprivation (2 or 24 hr) did not affect choice behavior at any age but did influence behavior in the goal box. These findings are discussed within the context of the changing demands faced by the rats during the weaning period.

Determinants of suckling versus drinking in weanling albino rats: influence of hydrational state and maternal contact

Preferences of weanling albino rats (15, 20, and 25 days of age) for nonnutritive suckling or drinking were determined using a Y-maze. Age, hydrational state, and the opportunity to contact the mother all influenced choice behavior. When tested in a maze that allowed continuous maternal contact in the "drinking-goal box," dehydrated rats chose to drink, while nondehydrated rats chose to suckle. Testing dehydrated rats in a maze that precluded maternal contact in the "drinking-goal box" eliminated drinking preference at all ages. These observations identify maternal presence as an important condition for the expression of drinking behavior during the weaning period and confirm our previous demonstration of dehydration's inhibition of suckling behavior.

Stimulation-induced ingestion in neonatal rats

Rat pups, 3, 6, 10 and 15 days old, received 500 ms pulse trains of electrical stimulation to the medial forebrain bundle (MFB) at the level of the lateral hypothalamus in the presence of milk. Pups receiving stimulation ingested more milk than littermate controls during a 30-min test at 3, 6 and 10 days of age. Day 15 pups did not. Stimulated pups through day 10 were more active than controls and exhibited the organized behaviors of mouthing, licking, gaping, stretch and even lordosis. Stimulated pups that ingested more milk continued to show increased activity through the 30-min test period, while the activity of control pups demonstrated a satiety effect. Milk augmented the activation of stimulation alone, increasing the incidence of all behaviors in 3-day-old pups and channelled the behavior of older pups into ingestion. Behaviors incompatible with ingestion such as lordosis were selectively inhibited by the presence of milk in stimulated day 10 pups. These results suggest a high degree of behavioral organization in neonatal rats than can be elicited by MFB stimulation and that becomes more goal-directed with age.

Olfactory contributions to dehydration-induced anorexia in weanling rats

By 20 days of age, dehydration produces a clear anorexia, even though weanling rats have had only limited feeding and drinking experience. Their lack of ingestive experience makes weanlings good subjects for studying the physiological mechanisms subserving anorexic phenomena because learned contributions are unlikely to add significant complications. Twenty-day-old rats dehydrated by hypertonic saline injection were anorexic when offered milk or solid food (rat chow), but not when offered sucrose solutions (Experiment I). However, when the scent of almond was associated with sucrose solutions, or with water, intake of these solutions was depressed by dehydration (Experiment II). Thus for dehydrated rats, olfactory stimulation may help produce dehydration-induced anorexia. Making rats anosmic by intransal lavage with ZnSO4 (Experiment III) eliminated the anorexia to almond-scented water and partially eliminated that to milk. For these fluids, an odor cue seems a requirement for the occurrence of dehydration-anorexia. In Experiment IV, we found that dehydration-anorexia did not occur when milk was infused directly into pups' mouths. This finding suggests that the inhibitory process mediating dehydration-anorexia influences the approach to food and not the actual consumatory response that occurs once food is in the mouth. The inhibition of feeding produced by dehydration, therefore, may depend largely on olfactory cues, and seems to operate at a distance, as rats locate and approach food.