c-Fos expression in hypothalamic nuclei of food-entrained rats

The present study aimed to identify the hypothalamic nuclei involved with food entrainment by using c-Fos-like immunoreactivity (c-Fos-IR) as a marker of functional activation. We studied rats entrained 3 wk to restricted feeding schedules (RF), their ad libitum (AL) controls, and the persistence of c-Fos-IR temporal patterns in entrained-fasted rats. In addition, we included 22-h fasting and 22-h fasting-refeeding groups as controls of fasting and refeeding acute effects. Diurnal patterns of c-Fos-IR were observed in the tuberomammilar nucleus (TM) and suprachiasmatic nucleus (SCN) in AL rats. In all nuclei, except the SCN and ventromedial nucleus (VMH), restricted feeding schedules imposed a temporal pattern of increased c-Fos-IR around mealtime. An increase in c-Fos-IR before and after meal time was observed in dorsomedial nucleus (DMH), lateral nucleus (LH), perifornical area (PeF), and TM, and a marked increase was observed in the paraventricular nucleus (PVN) after feeding. Food-entrained c-Fos-IR patterns persisted after 3 days in fasting in DMH, LH, and PeF. Present data suggest that FEO might not rely on a single nucleus and rather may be a distributed system constituted of interacting nuclei in which the PVN is mainly involved with the response to signals elicited by food ingestion and, therefore, with the entraining pathway. We can suggest that the PeF and TM may be involved with the arousal state during food anticipation and the DMH and LH with the time-keeping mechanism of FEO or its output.     

Antagonism of diazepam-induced feeding in rats by antisera to opioid peptides

Diazepam-induced feeding in rats is antagonized not only by the opiate antagonist naloxone but also intraventricular administration of specific antisera to the endogenous opioid peptides met-enkephalin or beta-endorphin. Pituitary beta-endorphin is probably not implicated in the diazepam effect since blockade with the glucocorticoid dexamethasone of the release of beta-endorphin from the anterior pituitary does not modify the diazepam-induced feeding, which is however prevented by TRH, a suggested physiological antagonist of some of the effects of opioid peptides. The possible central participation of both beta-endorphin and met-enkephalin in the ingestive behavior induced by diazepam gives further support to the postulated physiological role of endogenous opioids in appetite regulation.     

Infusions of naloxone into the medial preoptic area, ventromedial nucleus of the hypothalamus, and amygdala block conditioned place preference induced by paced mating behavior

Paced mating induces positive affect as revealed by conditioned place preference (CPP) in female rats. It has been suggested that endogenous opioids are involved in the generation of this positive affect since systemic administration of the opioid antagonist naloxone blocks mating-induced CPP. Several brain structures, including the medial preoptic area (mPOA), the ventromedial nucleus of the hypothalamus (VMH), the amygdala (Me), and the nucleus accumbens (Acb) have been implicated in the control of female sexual behavior. However, it is not known if these structures also participate in the positive affect produced by paced mating. To this end we determined the effects of intracranial administration of naloxone methiodide into the mPOA, VMH, Me and Acb on conditioned place preference induced by paced mating in female rats. Regardless of the site of infusion 5 μg of naloxone did not affect any of the sexual behavior parameters measured during copulation. When CPP was evaluated, the groups infused with naloxone into the mPOA, the VMH, and the Me before each conditioning session did not develop place preference. Only the group infused with naloxone in the Acb and the control groups did so. These results demonstrate that opioid receptors within the mPOA, VMH and Me are necessary for the rewarding aspects of paced mating. We suggest that the Me and VMH are important for the transmission of sensory information produced by copulation while the mPOA is the site where the positive affect is originated.     

Infusions of naloxone into the medial preoptic area,ventromedial nucleus of the hypothalamus,and amygdala block conditioned place preference induced by paced mating behavior

Paced mating induces positive affect as revealed by conditioned place preference (CPP) in female rats. It has been suggested that endogenous opioids are involved in the generation of this positive affect since systemic administration of the opioid antagonist naloxone blocks mating-induced CPP. Several brain structures, including the medial preoptic area (mPOA), the ventromedial nucleus of the hypothalamus (VMH), the amygdala (Me), and the nucleus accumbens (Acb) have been implicated in the control of female sexual behavior. However, it is not known if these structures also participate in the positive affect produced by paced mating. To this end we determined the effects of intracranial administration of naloxone methiodide into the mPOA, VMH, Me and Acb on conditioned place preference induced by paced mating in female rats. Regardless of the site of infusion 5 μg of naloxone did not affect any of the sexual behavior parameters measured during copulation. When CPP was evaluated, the groups infused with naloxone into the mPOA, the VMH, and the Me before each conditioning session did not develop place preference. Only the group infused with naloxone in the Acb and the control groups did so. These results demonstrate that opioid receptors within the mPOA, VMH and Me are necessary for the rewarding aspects of paced mating. We suggest that the Me and VMH are important for the transmission of sensory information produced by copulation while the mPOA is the site where the positive affect is originated.     

Butorphanol tartrate induces feeding in rats

Peripheral administration of butorphanol tartrate markedly enhanced feeding from 0800 to 1400 hours when compared with vehicle controls. Butorphanol tartrate feeding was not antagonized by doses of naloxone as high as 10 mg/kg. These data support the concept that the kappa or sigma opiate receptors are involved in feeding behavior.It is well recognized that the endogenous opiates play a role in the central regulation of appetite (1, 2, 3, 4). Numerous studies have shown that The endogenous opioid peptides and morphine can initiate feeding under various conditions (5–12) whereas the opiate antagonist, naloxine can reduce food consumption (13–20). Recently, the endogenous opiod peptide, dynorphin, has been reported to enhance food intake (12–25).Much evidence has been accumulated indicating that a number of opiate receptors are present in the brain, each one having a high affinity for a specific endogenous opioid peptide (26, 27). Both the cyclazocine related compounds (28) and the feeding enhancer, dynorphin (29–32), have been reported to be specific kappa receptor agonists. In the present study, we report on the effect of the morphinan congener, butorphanol tartrate (33), on ingestive behaviour.     

Involvement of opioid receptor subtypes in rat feeding behavior

The short-acting opiate antagonist naloxone decreases food intake in three models of ingestive behavior: free feeding, food-deprivation induced feeding and deoxyglucose-induced feeding. Twenty-four hours after administration, the long-acting, mu1 selective antagonist naloxonazine inhibits food intake to the same extent as naloxone in freely feeding and food-deprived rats, but not in animals treated with 2-deoxyglucose. These results indicate that 1) opiates modulate feeding through multiple opioid receptor mechanisms, one of which is the mu subtype, and 2) the feeding observed in various experimental paradigms are modulated by different receptor subtypes. Furthermore, these results illustrate the usefulness of naloxone in defining a behavior as opioid but point out its limitations in discriminating between opioid receptor subtypes.     

Effects of naloxone and cholecystokinin on food and water intake in vasopressin-deficient rats (Brattleboro strain)

Opioid peptides and cholecystokinin (CCK) have been shown to play a role in regulation of feeding behavior. Another neuropeptide that has recently been suggested to be involved in feeding is vasopressin. We explored possible interactions between opiates, CCK and vasopressin in feeding regulation by studying feeding suppression produced by naloxone and CCK in Brattleboro (DI) rats, which are homozygous for diabetes insipidus and lack the ability to synthesize vasopressin. Ten DI and 15 age-matched Long Evans (LE) rats were food deprived for 14 hours on two different days and then injected with naloxone (2.5 mg/kg) on one day or saline on the other. Thirty minutes later the food was returned and food and water consumption were measured after 1, 3 and 4 hr. Naloxone suppressed the food consumption of both DI and LE rats but the suppression was greater for the DI rats. This result was specific to feeding as water consumption was suppressed in LE more than in DI rats. Two weeks later, the same rats were food deprived for 6 hours on two different days and then injected with CCK-8 (2.5 micrograms/kg) on one day and with saline on the other. Food was returned one minute after the injection and food and water consumption were measured 30 and 60 minutes later. Food intake was reduced equally for both DI and LE rats. Water intake was not reduced. The results suggest that the suppression of feeding by CCK does not require an intact vasopressinergic system. The greater feeding suppression by naloxone in DI rats may suggest that opiates are interacting with vasopressin in producing their effects on food intake.     

Naloxone-reversible stress-induced feeding and analgesia in the slug Limax maximus

Exposure to tail-pinch stress increased the thermal nociceptive thresholds and food intakes of the slug, Limax maximus. These stress-induced "analgesic" and feeding responses, which were similar to the behaviors observed after treatment with exogenous opiates, were blocked by the opiate antagonist, naloxone. These results indicate that exposure to stress increases endogenous opioid activity in slugs and induces various behavioral and physiological responses in a manner analogous to that reported in mammals.     

Minireview. Benzodiazepine-opiate antagonist interactions in relation to feeding and drinking behavior

Benzodiazepines reliably produce overconsumption of food and fluids. Opiate antagonists, naloxone and naltrexone, block the benzodiazepine-induced hyperphagia and hyperdipsia at low doses. Hence, activation of endogenous opioid mechanisms may be closely involved in the benzodiazepine facilitatory effects on ingestional behavior. Evidence is reviewed that opiate antagonists diminish feeding and drinking responses, and may enhance satiety processes in feeding and drinking, in addition to selectively diminishing the palatability of attractive foods and fluids. It is proposed that a single mechanism of action of the opiate antagonists would be sufficient to account for both effects on feeding and drinking. Biochemical data confirm that acute benzodiazepine treatment in vivo is associated with a naloxone-reversible release of striatal enkephalin. It is possible therefore that there is a close association between the behavioral and biochemical data, which both show that acute benzodiazepine effects are reversed by opiate antagonists. The implied relationship between benzodiazepine and endogenous opioid mechanisms may be relevant to the question of concurrent opiate-benzodiazepine abuse.     

Patterns of Brain Activation and Meal Reduction Induced by Abdominal Surgery in Mice and Modulation by Rikkunshito

Abdominal surgery inhibits food intake and induces c-Fos expression in the hypothalamic and medullary nuclei in rats. Rikkunshito (RKT), a Kampo medicine improves anorexia. We assessed the alterations in meal microstructure and c-Fos expression in brain nuclei induced by abdominal surgery and the modulation by RKT in mice. RKT or vehicle was gavaged daily for 1 week. On day 8 mice had no access to food for 6–7 h and were treated twice with RKT or vehicle. Abdominal surgery (laparotomy-cecum palpation) was performed 1–2 h before the dark phase. The food intake and meal structures were monitored using an automated monitoring system for mice. Brain sections were processed for c-Fos immunoreactivity (ir) 2-h after abdominal surgery. Abdominal surgery significantly reduced bouts, meal frequency, size and duration, and time spent on meals, and increased inter-meal interval and satiety ratio resulting in 92–86% suppression of food intake at 2–24 h post-surgery compared with control group (no surgery). RKT significantly increased bouts, meal duration and the cumulative 12-h food intake by 11%. Abdominal surgery increased c-Fos in the prelimbic, cingulate and insular cortexes, and autonomic nuclei, such as the bed nucleus of the stria terminalis, central amygdala, hypothalamic supraoptic (SON), paraventricular and arcuate nuclei, Edinger-Westphal nucleus (E-W), lateral periaqueduct gray (PAG), lateral parabrachial nucleus, locus coeruleus, ventrolateral medulla and nucleus tractus solitarius (NTS). RKT induced a small increase in c-Fos-ir neurons in the SON and E-W of control mice, and in mice with surgery there was an increase in the lateral PAG and a decrease in the NTS. These findings indicate that abdominal surgery inhibits food intake by increasing both satiation (meal duration) and satiety (meal interval) and activates brain circuits involved in pain, feeding behavior and stress that may underlie the alterations of meal pattern and food intake inhibition. RKT improves food consumption post-surgically that may involve modulation of pain pathway.     

Naltrexone administered to central nucleus of amygdala or PVN: neural dissociation of diet and energy

There is evidence that opioids may affect food consumption through mechanisms as diverse as reward or energy metabolism. However, these hypotheses are derived from studies employing peripheral or, more rarely, intracerebroventricular administration of drugs. Opioid receptors have a wide distribution in the central nervous system and include a number of regions implicated in food intake such as the hypothalamic paraventricular nucleus (PVN) and the central nucleus of the amygdala (ACe). It is not known whether local opioid receptor blockade in either of these regions will produce similar effects on food intake. To examine this issue, a chronic cannula was aimed at either the PVN or ACe of rats that were fed a choice of a high-fat and high-carbohydrate diet, which allows for the measurement of both preference and total energy consumption. Naltrexone influenced preferred and nonpreferred food consumption, depending on the site of administration. Consumption of both preferred and nonpreferred diets was suppressed after PVN naltrexone administration, whereas only preferred diet intake was reduced after ACe injection of naltrexone. The present evidence indicates that direct stimulation of different brain regions with naltrexone may be associated with diverse effects on diet selection, which may be accounted for by manipulation of specific functional neural circuitry.     

Suppression of appetitive behavior in the rat by naloxone: lack of effect of prior morphine dependence

Naloxone (0.3–10 mg/kg) produced a dose-related suppression of eating and drinking in rats that had been deprived of food for 48 hr or water for 24 hr. The suppression of water intake by naloxone was unaltered in rats that had been physically dependent upon morphine one week earlier and which were tolerant to the analgesic effect of morphine at the time naloxone was tested. These results confirm the ability of naloxone to suppress appetitive behavior in the rat but do not resolve the issue of whether or not this effect of naloxone is the consequence of an interaction with an endogenous opioid system.     

Naloxone's effect on meal microstructure of sucrose and cornstarch diets

The opioid receptor antagonist naloxone decreases consumption of high-sucrose diets but does not reduce cornstarch diet intake in energy-restricted rats. Sucrose-fed rats eat at a much higher rate, consuming more food than cornstarch-fed rats. We examined meal microstructure using an automated weighing system in food-restricted rats eating either a high-sucrose or high-cornstarch diet. Sucrose-fed rats exhibited a higher rate of eating during their first meal compared with cornstarch-fed rats (0.34 vs. 0.20 g/min, respectively). However, naloxone did not reduce eating rate in either group. Naloxone decreased the size of the first meal in both diet groups by shortening the length of the meal. Naloxone's anorectic effect was more potent in the sucrose-fed rats. These results indicate that naloxone's heightened anorectic effect on sucrose diet consumption is not "rate dependent." Naloxone's anorectic actions may be modulated by two conditions, the sensory properties of food and the energy state of the animal. Thus the elevated anorectic potency of naloxone in energy-restricted sucrose-fed rats may reflect actions on neural systems that mediate orosensory and/or postingestive signals.     

The effects of aging on opioid modulation of feeding in rats

Feeding responses to naloxone and butorphanol tartrate were measured in Fisher-344 rats with ages of 2, 12, 22 and 28 months. The two younger groups were 10–100 times more sensitive than the older groups to the suppressive effects of naloxone on feeding. Additionally, the older rats were less responsive to the feeding enhancement following butorphanol injections. These results are consistent with reports of age-related changes in endogenous opioid systems.     

Naloxone blockade of growth hormone-releasing factor-induced feeding

The opiate antagonist naloxone was used to examine the possibility that endogenous opioid function is involved in the expression of the increased feeding observed following intracerebroventricular (i.c.v.) administration of rat hypothalamic growth hormone-releasing factor (GRF). It was found that systemically administered naloxone (0.125, 0.25 and 0.50 mg/kg) significantly suppressed the increased food intake observed following i.c.v. GRF (4.0 pmol) treatment. Though potent enough to eliminate ingestive effects of GRF, baseline food intake was unaffected by 0.125 mg/kg naloxone. Examination of 0.4, 4.0 and 40.0 pmol i.c.v. administered GRF-(3-40), a structurally related but physiologically inactive peptide, revealed no effect on food intake. The present results suggest involvement of endogenous opioid function in GRF-stimulated feeding.     

Effects of the selective kappa opioid antagonist, nor-binaltorphimine, on electrically-elicited feeding in the rat

Lateral ventricular injections of the 'nonspecific' opioid antagonist naloxone (100 micrograms) and the kappa-selective opioid antagonist nor-binaltorphimine (50 micrograms) elevated the electrical brain stimulation frequency threshold for eliciting feeding behavior. Mesopontine aqueductal injections of nor-binaltorphimine, on the other hand, lowered the feeding threshold while naloxone still elevated threshold. These findings suggest the existence of forebrain kappa receptors at which endogenous opioid activity results in a facilitation of feeding while kappa receptors in the brainstem seem to mediate an inhibitory effect.     

The role of cholecystokinin octapeptide in the central control of food intake in the dog

Cholecystokinin octapeptide (CCK-8, 1, 190 pmol/5 min) decreased food intake and water consumption in two models of ingestive behavior, i.e., food deprivation-induced feeding and insulin-induced feeding, when administered into the third (3V) and lateral (LV) cerebral ventricles. In fasted dogs, the suppression of food intake was more prominent after 3V CCK-8, whereas intravenously administered CCK-8 was without effect. Neuropeptide Y (NPY, 1, 190 pmol) had no significant stimulatory effect on food intake and water consumption in fasted as well as satiated dogs, and actually reduced both food and water intake in insulin-treated dogs. There was a slight but significant decrease in food and water intake after 275 nmol naloxone administration in both feeding models, and some of the dogs vomited. In insulin-treated animals, CCK-8 reversed, but NPY potentiated the hypothermic phase of temperature response observed after saline administration, whereas naloxone failed to alter rectal temperature. These results suggest that the effect of CCK-8 on feeding seems to involve central mechanisms in the dog, and that the mechanisms by which CCK-8, NPY and naloxone affect feeding behavior are different.     

Paraventricular nucleus lesions abolish the inhibition of feeding induced by systemic cholecystokinin

Peripherally administered cholecystokinin (CCK) initiates a behavioral syndrome which includes reduced food consumption and reduced exploratory behaviors. Previous studies suggest that CCK stimulates receptors in the gut, activating the vagus nerve, which relays sensory information to the nucleus tractus solitarius (NTS) and its ascending pathways. Terminal regions of ascending NTS projections include the paraventricular nucleus of the hypothalamus (PVN), the central nucleus of the amygdala (CNA), and the bed nucleus of the stria terminalis (BNST). Lesions of these three target sites were performed in rats to test the hypothesis that structures postsynaptic to the NTS mediate the behavioral syndrome induced by CCK. Knife cut lesions of the PVN abolished the reductions in feeding induced by CCK (5 and 10 micrograms/kg IP), as compared to sham lesioned control rats. PVN lesions only partially attenuated the reductions in exploration induced by CCK (2.5, 5, and 10 micrograms/kg IP), as compared to sham lesioned control rats. Electrolytic lesions of the CNA partially attenuated the reductions in exploratory behavior induced by CCK (2.5, 5, and 10 micrograms/kg IP), and had no effect on the reductions in feeding induced by CCK (5 and 10 micrograms/kg IP). Electrolytic lesions of the BNST had no effect on either the reductions in feeding or the reductions in exploration induced by CCK. The PVN appears to be one critical forebrain target site for mediating the actions of CCK on feeding. The CNA appears to facilitate the actions of CCK on exploration. Individual components of the behavioral syndrome induced by CCK may be mediated by anatomically distinct forebrain loci.     

Ventricular, paraventricular and circumventricular structures involved in peptide-induced satiety

Cholecystokinin, bombesin or gastrin (2 microliter of 50 ng/microliter) was injected stereotaxically into the paraventricular nucleus of the hypothalamus, the arcuate/ventromedial area, the subfornical organ, the area postrema and the cerebral aqueduct of Sprague-Dawley rats and the effects of these injections on food and water intake were studied. While the injection of cholecystokinin reduced food intake when it was injected into both hypothalamic loci, food and water intake were most severely affected by the injection of this peptide into the cerebral aqueduct. Bombesin reduced food intake after its injection into all areas except the subfornical organ and reliable reductions in water intake were seen after injection of this peptide into all areas except the paraventricular nucleus. Minor reductions in food intake were seen following gastrin injection into the paraventricular nucleus while increased water consumption was observed after this peptide was injected into the paraventricular nucleus and cerebral aqueduct. In a second study 6-hydroxydopamine injections (2 microliter of 8 micrograms/microliter were made into the five areas studied 10 days before animals were injected with 100 micrograms/kg of cholecystokinin (i.p.). All 6-hydroxydopamine-injected animals reduced their food and water intake in response to the cholecystokinin challenge as did intact controls. These results indicate that while the changes in food and water intake produced by the central injection of cholecystokinin, bombesin or gastrin may involve central catecholamine systems, those occurring after its systemic administration do not. Therefore, if the release of gastrointestinal peptides during natural feeding is part of a homeostatic mechanism regulating hunger and satiety, this mechanism may operate without directly involving central catecholamine systems.     

Narcotic antagonists attenuate drinking induced by water deprivation in a primate

Pure narcotic antagonists such as naloxone and naltrexone have consistently been shown to attenuate drinking in the rat after periods of water deprivation. One objective of this study was to extend observations to a primate species, the squirrel monkey. Whereas naloxone and naltrexone have a greater relative affinity for opiate receptors preferentially binding morphine and other opiate alkaloids than for those with high affinity for the endogenous opioid peptides, diprenorphine, another pure opiate antagonist, binds with equally high affinity to both receptor subtypes. Therefore, a second objective was to determine the actions of diprenorphine on drinking in water-deprived rats and squirrel monkeys and to compare the effects of this drug to those of naloxone and naltrexone. All three narcotic antagonists suppressed water consumption of monkeys and rats deprived of water for 18 and 24 hr, respectively. Diprenorphine was the most potent compound tested in both species, producing significant reductions in water consumption of monkeys and rats at systemic doses as low as 0.01 and 0.1 mg/kg respectively. Moreover, diprenorphine was the longest acting of the three drugs in the monkey. These results demonstrate that the narcotic antagonists attenuate drinking in primates as well as in rodents and support the hypothesis that these drugs reduce water intake by interrupting the activity of endogenous opioid pathways mediating drinking behavior.