Selective reduction by dexamethasone of stress-related hyperphagias

Effects in the rat of intranigral morphine and DAGO on eating and gnawing induced by stress

Stress produced by pinching the tail is known to increase feeding behavior in rats, and endogenous opioids have been implicated in the mediation of this effect. We have reported previously that a nonspecific opioid antagonist and a mu-selective antagonist decrease this stress-induced eating (SIE) when they are microinjected into the substantia nigra (SN). The present study investigated the possibility that activation of opioid receptors in the SN might also alter SIE. Because oral stereotypy and nociception are affected by opioid mechanisms in the SN, measurements of gnawing and of tail flick and hot plate response latencies were also made. Bilateral injection of morphine (0.1-20 nmol) and the mu-selective agonist D-Ala2,N-Me-Phe4,Gly5-ol-enkephalin (DAGO; 0.03-1 nmol) increased response latency on the hot plate test and decreased gnawing produced by tail pinch. Tail flick latency and SIE were not affected. It is concluded that activation of opioid receptors in the SN does not produce an alteration in SIE as has been seen with opioid antagonists.

Microinjection of opioid antagonists into the substantia nigra reduces stress-induced eating in rats

Stress produced by pinching the tail has been shown to cause satiated animals to eat and to display oral stereotypies. Endogenous opioids and central dopamine systems have been implicated in the mediation of these effects. In order to test the possibility that the substantia nigra (SN) might be involved, the amount of food intake and gnawing produced by mild tail pinch were assessed following bilateral microinjections of opioid antagonists into the SN. Evaluations of nociceptive thresholds were also conducted using tail flick and hot plate tests. Eating induced by tail pinch was reduced by microinjections of the non-selective opioid antagonist naloxone (3, 10, 20 and 30 nmol) and by the mu-selective antagonist Cys2, Tyr3, Orn5, Pen7 Amide (CTOP) (1, 3 and 10 nmol). These effects on eating occurred in the absence of effects on gnawing. kappa- and delta-antagonists (10 nmol) had no effect on eating or gnawing. Naloxone did not alter either tail flick or hot-plate response latencies. The highest dose of CTOP increased response latency on the hot-plate test only. The results are interpreted as suggesting that the SN may be an important central site of action for opioid antagonists in reducing stress-induced eating. The possibility that the SN may be a central site mediating the effects of dopamine on this phenomenon is also discussed.

Glucocorticoids potentiate the dipsogenic action of angiotensin II

The effect of a short-term, acute treatment with a glucocorticoid, dexamethasone sodium phosphate, on the drinking induced by angiotensin II (AII) was investigated in a series of experiments. Initial studies indicated that a single injection of dexamethasone (700-750 micrograms/kg, i.p.) reduced food intake, body weight and water intake for up to 48 h, but had little effect on blood pressure when it was measured 6 h subsequent to the injection. The drinking elicited by peripherally administered AII (200 micrograms/kg, s.c.) was enhanced if the glucocorticoid (700 micrograms/kg, i.p.) was given 3 h or 6 h prior to the dipsogen. There was no effect of pretreatment with the steroid if the drinking test was delayed by 24 h. The subsequent experiment showed that the glucocorticoid effect on AII-stimulated drinking was dose dependent (100 micrograms-1600 micrograms/kg). The drinking stimulated by intracerebroventricular (i.c.v.) AII (2.5 ng) was enhanced in terms of volume and total duration by prior treatment with dexamethasone, but i.c.v. carbachol (200 ng)-induced drinking remained unaffected. The final study showed that binding of AII to its receptors in five different areas of the rat brain was not affected by prior treatment with dexamethasone.

Intracerebroventricular alloxan reduces 2-deoxy-D-glucose analgesia

2-Deoxy-D-glucose (2DG) analgesia, mediated in part by endogenous opiate and hypothalamo-hypophysial systems is presumably activated by its stress-related properties. Recently 2DG hyperphagia, but not 2DG hyperglycemia was reduced by central pretreatment with the pancreatic beta-cell toxin, alloxan; this deficit was eliminated by co-administration of 3M D-glucose. The present experiment examined whether intracerebroventricular pretreatment with alloxan (40 or 200 micrograms) altered 2DG analgesia (400 or 700 mg/kg, IP) on the tail-flick and jump tests, and whether 3M D-glucose co-administration ameliorated any deficits. Both alloxan doses significantly reduced 2DG analgesia (400 mg/kg) on both tests. 2DG analgesia (700 mg/kg) was significantly reduced by both alloxan doses on the jump test, but only by the higher alloxan pretreatment on the tail-flick test. 3M D-glucose co-administration ameliorated alloxan-induced analgesic deficits more effectively at the lower 2DG dose. Neither alloxan nor alloxan/3M D-glucose treatments altered basal thresholds. These data pertain both to alloxan's effects upon coding of 2DG effects as stressful, and to the role of diabetes and/or central glucoreceptors in analgesic processes.

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.

Genetically obese (ob/ob) mice are hypersensitive to glucocorticoid stimulation of feeding but dramatically resist glucocorticoid-induced weight loss

The genetically obese (ob/ob) mouse is hyperphagic and hypercorticosteronemic; both hyperphagia and excessive weight gain are ameliorated by adrenalectomy. We report here that corticosterone or dexamethasone stimulate feeding in obese mice at one-fifth the dose needed to increase feeding in lean littermates. Metabolic weight loss, a measure of carbon dioxide and water lost due to respiration, is stimulated by glucocorticoids. Yet we find that obese mice are only one-seventh as sensitive as lean mice to the enhancement of metabolic weight loss following corticosterone. Therefore, hypersensitivity to glucocorticoid-induced feeding and hyposensitivity to glucocorticoid-stimulated weight loss may act in tandem to produce the ob/ob's exaggerated weight gain.

Experimental manipulations of eating: advances in animal models for studying anorectic agents

The material set out in this text has been designed to show the wide range of procedures which have the capacity to modify eating behavior--to produce hyper- or hypophagia, to alter the profile of eating patterns, or to adjust dietary preferences and selection. Accordingly, in investigating anorectic drugs it seems necessary to observe the effects of drug actions in a variety of experimental models. This strategy will provide a more complete description of the effect of a drug, will throw light on the mechanism of action, and will provide a more realistic base for predicting the effects of drugs in man.

Vasopressin and glucoprivic-feeding behavior: a new perspective on an 'old' peptide

The feeding responses induced by systemic administration of 2-deoxy-D-glucose (2-DG) and paraventricular hypothalamic injection of norepinephrine were assessed in Brattleboro rats deficient in vasopressin (VP). Controlling for the non-specific complications of diabetes insipidus, it was found that Brattleboro rats have a deficient 2-DG-feeding response, but an essentially normal noradrenergic-feeding response. Specific carbohydrate appetite abnormalities were also demonstrated. It is argued that VP influences 2-DG feeding by mobilizing endogenous energy stores following its acute release from the hypothalamoneurohypophysial system. A new function is thus ascribed for VP and the neural lobe of the pituitary. It is suggested that VP plays a role in stress-induced feeding and in specific aspects of carbohydrate appetite. The potential relevancy of vasopressin perturbations to bulimia nervosa and to the Prader-Willi obesity syndrome is also discussed.

Starvation-induced changes in rat brain corticotropin-releasing factor (CRF) and pituitary-adrenocortical response

Starvation-induced changes in CRF concentration in major brain regions and abnormalities in the pituitary-adrenal axis were examined in rats using rat CRF radioimmunoassay. The CRF concentrations in the hypothalamus and cerebellum were significantly reduced in the completely starved rats, while those in the midbrain, thalamus and neurointermediate lobe of the pituitary were significantly increased in the semi-starved or completely starved rats. No significant changes in the CRF concentrations were found in the pons, medulla oblongata and cerebral cortex. In the completely starved rats, the serum ACTH level was significantly reduced, whereas the serum corticosterone level was markedly elevated. These observations suggest that starvation may stimulate the CRF-ACTH-corticosterone system and that not only hypothalamic CRF but also extrahypothalamic CRF may be discretely related to feeding behavior or starvation. The reduced serum ACTH level in starved rats may be ascribed to the negative feedback effect of the elevated serum corticosterone.

The effect of dexamethasone on vascular permeability of experimental brain tumours

The vessels of experimental gliomas show an abnormally high permeability to small polar molecules, such as mannitol. To establish whether this change in vessel permeability is modified by treatment with the corticosteroid dexamethasone, the kinetics of [14C]mannitol transfer into rat astrocytomas were estimated in both steroid-and saline-treated, tumour-bearing animals. This was achieved by injecting [14C]-mannitol i.v., using a specially devised technique, so as to maintain a constant concentration of tracer in the blood plasma. In separate experiments steady levels of the tracer were maintained in the circulation from 1 to 30 min. Mean plasma and tumour radioactivity were measured, and the apparent transfer constant of mannitol across the vascular endothelium and the size of the extravascular extracellular mannitol space in the tumours were calculated. Despite a significant clinical improvement in the treated animals and adequate circulating levels of dexamethasone at the time of the permeability studies, no difference in either the apparent transfer constant for the movement of mannitol into the tumours or the fractional extracellular mannitol space was detected between these animals and the controls. With steroid treatment both tumour-bearing and non-tumour bearing animals lost weight, and in the latter there was no consistent change in routine biochemical or haematological parameters. It was concluded that under these conditions it is unlikely that clinical improvement with dexamethasone therapy was due to a non-specific reduction in tumour vessel permeability to polar substances.

Hyperphagia induced by 2-deoxy-D-glucose in the presence of the delta-opioid antagonist ICI 174,864

The effect of the selective delta-opioid antagonist ICI 174,864 (N,N-bisallyl-Tyr-Aib-Aib-Phe-Leu-OH: Aib=alpha-aminoisobutyric acid) on the hyperphagia induced by 2-deoxy-D-glucose (2-DG) was investigated in non-deprived rats. The increase in food intake produced by 2-DG (500 mg/kg i.p.) was not reduced by ICI 174,864 at a dose (3 micrograms/rat i.c.v.) which totally abolished the feeding response to the delta-agonist D-Ala2-D-Leu5-enkephalin (10 micrograms/rat i.c.v.). These findings suggest that the appetitive effects of 2-DG are not mediated by an enkephalinergic/delta-receptor system. They do not, however, preclude the possible involvement of endogenous opioids acting at other sub-types of opioid receptor in this glucoprivic ingestional response, which is suppressed by less specific opioid antagonists such as naloxone.

Sugar, opioids and binge eating

There is evidence that endogenous opiates are involved in the control of feeding in experimental animals. Several types of experimental obesity are associated with increased opiate production and/or increased numbers and sensitivity of opiate receptors. Research with experimental animals suggests that nutrients, particularly sugar, have an effect on feeding behavior that is mediated by opiates. For instance, the obesity-producing effect of a palatable diet in rodents is blocked by opiate antagonists. Stress induced feeding in rodents leads to preferential sucrose ingestion and is blocked by opiate antagonists and beta-endorphin. The effect of nutrients on the endogenous opiate system of humans is less clear. Clinical experience suggest that carbohydrates (sugar in particular) play a role in binge eating and obesity. Many binge eaters preferentially eat sweets during a binge. Many obese individuals consume more than half of their total daily calories as carbohydrates. Sweet snacking is a frequent behavior at times of stress. Recent evidence suggests that sugar can lead to increased beta-endorphin production in obese subjects.

Experimental dissociation of food intake and plasma beta-endorphin following 2-deoxy-D-glucose in rats

The present studies were undertaken to further assess the role of plasma beta-endorphin (beta-EP) in the hyperphagia induced by the glucose antimetabolite, 2-deoxy-D-glucose (2-DG). Plasma concentrations of immunoreactive beta-EP (ir-beta-EP) were measured at the end of the first hour of feeding in all animals treated with 400 mg/kg 2-DG. Previous studies had shown a consistent, positive association between 2-DG hyperphagia and plasma ir-beta-EP concentrations, but the present data revealed dissociations between hyperphagia and plasma ir-beta-EP. Dexamethasone administration blocked the 2-DG-induced rise in plasma ir-beta-EP, but had no effect on the 2-DG hyperphagia measured at 1 hour. Forced drinking of a 2% NaCl solution decreased 2-DG hyperphagia, but not the 2-DG induced rise in plasma ir-beta-EP. Thus, elevations in plasma ir-beta-EP are not necessary for the full expression of 2-DG-induced hyperphagia in dexamethasone-treated rats. Furthermore, decreased feeding responses to 2-DG could coexist with increased levels of plasma ir-beta-EP in NaCl-treated normal rats. Elevations in plasma ir-beta-EP do not appear to be the critical opiate link in 2-DG induced hyperphagia.

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.

Plasma immunoreactive beta-endorphin response to glucose ingestion in human obesity

Following the oral administration of 100 g of glucose, morbidly-obese subjects and non-obese controls demonstrated increased levels of plasma immunoreactive beta-endorphin. There was a slow rise in plasma immunoreactive beta-endorphin in the non-obese controls throughout the 3-h observation period. The obese subjects demonstrated a delayed and significantly greater rise of plasma immunoreactive beta-endorphin, when compared to the controls. These findings may have implications for further research in human obesity.

Adrenal modulation of the inhibitory effect of corticotropin releasing factor on feeding

Corticotropin releasing factor (CRF) reduces food intake in rats after central administration. In these studies we examined whether the adrenal gland and the vagus were involved in CRF suppression of intake. One hour intake was reduced by a 5 micrograms (ICV) injection of CRF in sham but not adrenalectomized rats maintained on 0.9% NaCl. In a separate experiment on rats maintained on tap water, the inhibitory effect of CRF (5 micrograms) lasted at least 4 hours in sham rats whereas adrenalectomized rats did not significantly differ from controls. These experiments suggest that the adrenal gland modulates the feeding response to CRF. As replacement with corticosterone (0.75 mg/kg) in total adrenalectomized rats did not restore responsiveness to 5 or 10 micrograms of CRF, we next studied whether the adrenal medulla was responsible for the decreased responsiveness to CRF. In rats lacking the adrenal medulla only, food intake was reduced by a 5 microgram injection of CRF; in sham rats, intake was significantly reduced by doses as low as 0.1 microgram of CRF. An additional experiment examined the effect of gastric vagotomy on the CRF feeding response. Vagotomized rats were as responsive to 5 and 10 microgram injections of CRF as sham rats, which suggests that the effect is not dependent on the vagus nerve. These findings indicate that the adrenal gland, primarily the medulla, plays an intermediate role in the reduction of food intake caused by central injections of CRF. This conclusion is consistent with the known effect of CRF on adrenomedullary discharge.

Dissociation of analgesic and hyperphagic responses following 2-deoxy-D-glucose

Injection of 2-deoxy-D-glucose (2DG) elicits both analgesic and hyperphagic responses in rats. While pituitary dysfunction, decreased dopamine availability, or neonatal monosodium glutamate treatment decreases 2DG hyperphagia, they increase 2DG analgesia. In contrast, 2-DG analgesia alone is decreased by repeated 2-DG injections, while 2-DG hyperphagia alone is decreased following naloxone pretreatment. The present four experiments examined further mechanisms subserving these two induced responses. In the first experiment, rats were deprived of food for 6 h following 2-DG (600 mg/kg). While 2-DG hyperphagia persisted in the absence of glucoprivation, 2-DG analgesia failed to occur after this delay. In the second experiment, acute exposure to inescapable foot shock (4 mA, 0.5 s/5 s for 1 h) preceded administration of 2-DG (600 mg/kg). While 2-DG hyperphagia was eliminated by this procedure, 2-DG analgesia was significantly potentiated. In the third experiment, repeated morphine (10 mg/kg) injections over 14 days eliminated 2-DG analgesia on the fifteenth day, but failed to affect 2-DG hyperphagia. In the fourth experiment, lesions placed in either the lateral hypothalamus or zona incerta decreased 2-DG hyperphagia, but failed to affect 2-DG analgesia. These results are discussed in terms of common and dissociative mechanisms mediating both responses.

Opioid modulation of appetite

The discovery of opiate receptors and endogenous opioid peptides within the central nervous system has resulted in a number of speculations concerning the physiological significance of these peptides. In the present article, we review the evidence suggesting a primary role for some of the opioid peptides as regulators of ingestive behavior. In particular, we elaborate a hypothesis in which we suggest that in some species opioid peptides may play a role as a tonic inducer of ingestive behaviors, held in check by a variety of neuropeptides and monoamines. This review explores in detail the role of the opioid peptides as major mediators of the reward system and as a link between reward and feeding behaviors. Finally, a teleological role for opioid peptides in species preservation, which may explain the discrepancies in the role of the opioid peptides in feeding behavior in different species is proposed. It is suggested that the feeding profile of the animal provides important clues as to whether or not the animal has an opiate-sensitive feeding system. We stress that interactions with ingested nutrients and the milieu interieur provide an important means by which animals modulate the opiate-entrained feeding drives.

Minireview. Stress induced eating

The relationship of oral behaviors to stress has long been recognized both in humans and in wild animals. In the last decade numerous advances have been made in our understanding of stress-induced feeding predominately because of the development of the simple tail-pinch model of stress induced feeding in rats. Present evidence strongly implicates monoamines and the endogenous opioid peptides as well as other neuropeptides as playing a role in the central regulation of stress-induced eating.

Relationship between plasma concentrations of immunoreactive beta-endorphin and food intake in rats

Periods of increased food intake in male rats were characterized by significant elevations in the plasma concentrations of immunoreactive beta-endorphin (beta-ep). Administration of 2-deoxy-D-glucose (400 mg/kg) produced rapid and concurrent increases in both food intake and plasma beta-ep. Administration of insulin (10 units/kg) produced large delayed increases in food intake but only modest delayed increases in plasma beta-ep. Spontaneous nocturnal feeding was associated with increased plasma beta-ep. Increases in daytime food intake in rats subjected to 24 hr of food deprivation were also characterized by elevated plasma beta-ep. In all cases examined, those feeding behaviors in male rats which were subject to inhibition by naloxone were characterized by elevated concentration of plasma beta-ep.

Circulating opioids: possible physiological roles in central nervous function

Evidence is reviewed regarding the release of endorphins by such diverse conditions as stress, long distance running, acupuncture, sexual activity, suggestion and ritualistic dancing ceremonies. Additional evidence is cited regarding possible physiological roles of endorphins in antinociception, socialization, euphoria, some mental disorders, drive states and vegetative functions. The concentration of this latter type of evidence is on conditions during which endorphins seem to be exerting effects on a number of different systems together (for example, euphoria is almost always accompanied by analgesia), and the possibility is suggested that the activation of a number of functions together may be due to a global activation of opiate receptors throughout the CNS. A possible basis for this global activation arises from results from this laboratory indicating the presence of a blood-borne opioid hormone, secreted by the pituitary or by an endocrine gland under pituitary control, which is capable of passing from the blood into the CNS. This diffuse endorphinergic system, which is complementary to the well-established endorphinergic neuronal systems in the CNS, thus derives its property of global action on opiate receptors by the diffuse means by which the hormone reaches its target sites, i.e., by passing through the blood brain barrier. Thus, while each specific endorphin-mediated function can be activated by the activation of its respective neural pathway, it is proposed that the hormonal endorphinergic mechanism is activated to produce a global response provoked by conditions to which a more generalized response, including physiological and behavioural changes, is most appropriate.

Drinking, but not feeding, is opiate-sensitive in hamsters

The long-lasting opiate antagonist, naltrexone (NTX), was examined for its effects on various types of consummatory behavior in male golden hamsters and rats. Rat, but not hamster, 24 hr food and water intakes were significantly decreased by four daily NTX (10.0 mg/kg) injections. Hamsters displayed a minimal night to day feeding ratio compared to rats. Hamsters increased food intake following insulin (50 U/kg) administration, but not after 24 hr food deprivation (FD) or 2-deoxy-D-glucose (2-DG; 800 mg/kg) injections. NTX (1.0 and 10 mg/kg) had no effect on feeding, but markedly attenuated hamster drinking induced by 48 hr water deprivation or hypertonic saline injection. Dexamethasone (DEX), a glucocorticoid which depletes pituitary beta-endorphin and produces anorexia in rats, had no effect on daily hamster intake. Since the normal feeding profile of the hamster is similar to that of naloxone and DEX-treated rats, hamsters appear to lack an opiate-sensitive feeding system. In contrast, stimulated drinking behavior of hamsters operates through an opiate-sensitive mechanism. Thus, there are marked species differences concerning the involvement of endogenous opioids in consummatory behavior.

Modulation of antinociceptive responses following tail pinch stress

Mild, non-noxious, oscillating pinches to a rat's tail elicits hyperphagia. The present study examined whether tail-pinch (TP) would exert hyperalgesic and hyperactive effects in rats that also exhibit the overeating response. The first experiment assessed TP effects upon reactivity to electric shock as measured by flinch-jump thresholds. Significant decreases in jump thresholds were observed 0 and 15, but not 30, min following TP. This effect persisted regardless of whether food was present or absent during TP. The second experiment assessed TP effects upon reactivity to heat as measured by hot-plate latencies. In contrast to jump thresholds, the shortened hot-plate latencies observed following TP persisted into the recovery period. In examining TP effects upon activity levels (Experiment 3), it was found that animals display similar patterns of temporally-declining activity regardless of whether TP was administered or not. Finally, TP selectively decreased the analgesic responses to two different doses of morphine and two different cold-water swim temperatures (Experiment 4). The TP-induced reductions occurred when TP was administered either before or after the analgesic manipulation. These data are discussed in terms of the nociceptive selectivity of the TP effect, and its influences upon analgesic processes.

Stereoselective effects of opiate agonists and antagonists on ingestive behavior in rats

In male Sprague Dawley rats, the (-)-isomer of the opiate antagonist GPA 1843 (beta-9-methyl-5-phenyl-2-allyl-2'-hydroxy-6, 7-benzomorphan) produced dose-related decreases in nocturnal feeding and of hyperphagias induced by 2-deoxy-D-glucose (2-DG; 400 mg/kg) and 24 hr food deprivation (FD). The hyperphagia induced by insulin (10 U/kg) was not significantly decreased by GPA 1843. In contrast, comparable doses of the (+)-stereoisomer, GPA 1847, had no effect on nocturnal, 2-DG or FD hyperphagia. In addition, hyperphagia and hyperdipsia were observed following administration of the opiate agonist levorphanol, but not its stereoisomer, dextrorphan. Thus, the effects of these agents on consummatory behavior are mediated by a stereospecific interaction with opiate receptors, which further indicates that endogenous opiate peptides are involved in the expression of these opiate-related hyperphagias.