Neuropeptides in the mechanisms of the activation of escape reactions induced by stimulation of the ventromedial hypothalamus during food motivation satiation

Influence of food intake on hypothalamically induced avoidance reactions have been studied in rabbits. It was shown that first contact with food and beginning of food intake accompany with activation of avoidance reactions. Central action of cholecystokinin-octapeptide, pentagastrin, beta-endorphin and naloxone on avoidance reactions of fed and fasted rabbits before and during food intake was investigated. It was found that injection of cholecystokinin and naloxone, which had a satiated effect, act on avoidance reactions similarly in fed and fasted rabbits. Beta-endorphin inhibits avoidance behavior, and only pentagastrin activates avoidance reactions of fasted but not fed rabbits. It is concerned that influence of feeding motivation may modulate avoidance behavior by participation of endogenous gastrin-like peptide release into the perineuronal area during contact of rabbits with food and beginning of its intake.     

Effect of sodium ion on the affinity of naloxone for the kappa opioid receptor

Several investigators have observed that sodium ion enhances the binding of naloxone to opioid receptors. This effect has generally been attributed to allosteric modulation of the state of the mu receptor. However, a recent claim has been made that the enhancement does not involve a change in the mu receptor, but instead occurs because naloxone becomes a more kappa-specific drug when sodium ion is present in high concentration. Since the claim was not based on experimental evidence from binding studies involving known high-affinity kappa ligands, we have investigated the competition of naloxone for the kappa site using [3H]U-69593 as the marker for receptor binding. Assays were carried out in the presence and absence of 100 mM NaCl. The results of the study indicate that sodium ion does not increase the affinity of naloxone or U-69593 for the kappa receptor.     

Further evidence that naloxone acts as an inverse opiate agonist: Implications for drug dependence and withdrawaL

To test if naloxone behaved as an inverse agonist rather than as an antagonist we evaluated its responses in guinea-pig ilea with and without morphine (480 nM, 24 h). In control ilea, naloxone (100 nM) had no effect. In morphine-treated ilea, naloxone as a bolus, but not as an infusion, elicited an abstinence response. Preadministration of naloxone blocked the response to subsequent administrations. Similarly, naloxone failed to produce an abstinence response in ilea pretreated with kappa compounds (bremazocine, U50488 or xorphanol 100 nM) or with kinase inhibitors (H7 or H8 30 μM). These findings can be interpreted in the light of the two-state receptor model if naloxone behaves as an inverse agonist: Incubation with morphine increased the active state of receptors making them susceptible to the inverse agonist (naloxone); exposure to naloxone favored the inactive conformation making them insensitive to further administration of naloxone; kappa compounds behaved as antagonists preventing the response to naloxone; and kinase inhibitors interfered with the active conformation making the system insensitive to naloxone. According to this model, dependence can be viewed as an overexpression of the active receptors and withdrawal as an abrupt change from the active to the inactive state.     

The site of action of naloxone in suppressing food and water intake in rats

Previous studies have shown that naloxone causes a decrease in food and water intake; however, the site of this action has not been determined. We investigated this problem by giving bilateral injections of 15 μg/rat of naloxone into the lateral ventricles of cannulated, food and water deprived rats. This treatment caused a significant decrease in food intake when compared to saline injected controls. Water intake in naloxone-treated animals did not differ significantly from that of saline-treated controls during the one hour test period. The total dose of naloxone given centrally, 15 μg, did not produce a change in eating or drinking if given peripherally. The findings imply that naloxone exerts its effect on food intake at a central site. A dose-related and significant suppression of water intake was seen after treatment with nalaxone peripherally (1, 3, and 10 mg/kg, i.p.) in rats with either subdiaphragmatic vagotomy (vag) or a sham vagotomy (sham). Although a significant suppression of food intake was seen in the sham rats, no supression of food intake was seeen in the vag rats at any dose of naloxone tested. In rats pretreated with methyl atropine (5 mg/kg, i.p.), naloxone (3 mg/kg, i.p.) was equivalent to saline in that it did not decrease food intake. However, nalaxone did cause a significant decrease in water intake in methylatropine pre-treated rats. These results suggest that the suppression of food intake by naloxone has a central site of action which is mediated by the vagus, and specifically by vagal efferents, since the effect was blocked by methylatropine. The results also suggest that naloxone's effect on water intake is mediated by a different mechanism than that involved with food intake.     

A dose-ratio comparison of mu and kappa agonists in formalin and thermal pain

The effects of putative mu and kappa agonists, with and without naloxone, were compared in the formalin and tail flick tests in rats. The mu agonist sufentanil was more potent in the tail flick test than the formalin test while the opposite was true for the kappa agonist ethylketocyclazocine (EKC). MR2034 was equipotent in the two tests and in the tail flick test, analgesia decreased at high doses. The naloxone (0.1 mg/kg) dose-ratios (DR) for sufentanil and EKC were 3 to 7 times larger for the tail flick test than the formalin test. From this and other DR studies it is argued that in thermal pain tests, opioid analgesia is mediated primarily by mu receptors while in non thermal tests kappa effects predominate.     

Suppression of food intake and body weight gain by naloxone in rats

The effect of acute and chronic administration of naloxone on food acquisition and weight gain in rats was studied in 3 experiments. One injection of a sparingly-soluble salt of naloxone in slow-release vehicle markedly lowered mean food intake over that of control rats injected with the vehicle only. Mean body weight of the naloxone-injected rats was significantly lower than that of the control group for one week.Repeated evening injections (2000 h) of naloxone hydrochloride in saline tended to reduce the night-time feeding below control levels throughout the 10-day period of naloxone administration. Food intake was significantly lower in the 4- and 8-h periods after the first injection of naloxone than that on the preceding saline control night. The initial decreases were offset by increased day-time feeding so that total daily food intake was not significantly altered over the 10 days. When saline was substituted for naloxone, food intake increased.Rats given naloxone following 24 h of fasting consumed significantly less food and gained less weight during 4 h of access to food compared to those receiving saline. After a 48-h fast naloxone-treated rats also gained significantly less body weight than those given saline, but the reduction in food intake was not statistically significant. These results suggest the possibility that endorphins may have a modulating effect on feeding activity.     

The potentiating effect of naloxone upon apomorphine-induced hyperthermia

Intravenous or intracerebroventricular pretreatment with the narcotic antagonist naloxone in rabbits significantly enhanced the magnitude of the hyperthermic response to the dopaminergic agonist apomorphine. Naloxone did not potentiate the hyperthermic action of either amphetamine or lysergic acid diethylamide. Apomorphine-in induced hyperthermia was sensitive to antagonism by haloperidol, cyproheptadine and p-chlorophenylalanine. However in rabbits pretreated with any of the above antagonists, administration of naloxone five minutes prior to apomorphine challenge restored the hyperthermic effect of apomorphine. Increasing the dose of the apomorphine challenge likewise surmounted the antagonism. It was concluded from these data that naloxone exerts a potentiating influence upon apomorphine drug effect in naive rabbits as well as rabbits pretreated with antagonists of apomorphine-induced hyperthermia.     

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.     

TENA, a selective kappa opioid receptor antagonist

A number of opioid antagonists (TENA, naloxone, Mr 2266, WIN 44441) were evaluated for their selectivity in antagonizing the effect of mu, kappa, and delta agonists in the guinea pig ileum (GPI) and mouse vas deferens (MVD) preparations. Among these four antagonists, TENA was the most potent and the only ligand which was selective for kappa receptors. In this regard TENA was approximately 27-times more effective in antagonizing the kappa agonist, U-50488H, relative to the mu agonist, morphine, and it was about 5-times more effective against ethylketazocine (EK) relative to morphine. At the same concentration (20 nM) TENA did not significantly antagonize the delta agonist, [D-Ala2,D-Ala5]enkephalin (DADLE), in the MVD. Also, TENA was more effective than naloxone, EK, or U-50488H in protecting kappa receptors from irreversible blockage by beta-CNA. The results of this study indicate that TENA is the most selective kappa antagonist yet reported.     

Opioid control of oxytocin secretion: evidence of distinct regulatory actions of two opiate receptor types

Stress induced oxytocin (OT) secretion was measured in female rats following treatment with various opiate antagonists selective for different types of opiate receptor. Naloxone (mu selective) and MR2266 BS (kappa selective) potentiated the OT response to an emotional stress (1 min. immobilization) whereas the delta selective antagonist ICI 154129 was without effect. Similarly, naloxone and MR2266 BS, but not ICI 154129, potentiated the response to a physical stress (i.p. hypertonic saline). A dose response comparison of the actions of naloxone and MR2266 BS revealed that naloxone was most effective in potentiating the immobilization response whereas MR2266 BS elicited greater responses than naloxone when administered prior to hypertonic saline. The results indicate that the opioid regulation of stress induced OT secretion is primarily mediated via mu and kappa opiate receptor types, the two types differentially regulating the OT response to two different stressors.     

Effects of auricular electrostimulation and naloxone on nociceptive sensitivity in rabbits

Auriculo-acupuncture electrostimulation (AES) (15 H2) decreased the amplitude of somatosensory evoked potential (EP) in response to tooth pulp electrostimulation in 64% of acupuncture-sensitive unanesthetized rabbits and didn't induce the changes of EP in 36% of animals (acupuncture-resistant rabbits). The systemic naloxone (0.2 mg/kg) injection reversed the AES analgetic effect and induced the hyperalgesic one in acupuncture-sensitive rabbits but induced the analgetic effect in acupuncture-resistant animals. It has been suggested that the differences of individual characteristics of endogenous opioid system determined different naloxone action in acupuncture-sensitive and acupuncture-resistant rabbits.     

Comparison of the endogenous heptapeptide Met-enkephalin-Arg6-Phe7 binding in amphibian and mammalian brain

In previous communications [4, 38] we published that [3H]Met-enkephalin-Arg6-Phe7 (MERF) binds to opioid (kappa2 and delta) and sigma2 sites in frog and rat brain membrane preparations, however no binding to kappa1 sites could be established. In the present paper we compare the frog, rat and guinea pig brain membrane fractions with respect to their MERF binding data. No qualitative differences were found between the three species but specific binding of labelled MERF was maximal in frog brain and lowest in guinea pig brain, which corresponds to their kappa2 opioid receptor distribution. The naloxone resistant binding was also present in all investigated species and varied from 25% in frog and guinea pig cerebrum, to 50% in rat cerebrum and cerebellum, but no naloxone inhibition was found in guinea pig cerebellum where no kappa2 opioid receptors have been found. The presence of sigma2-like receptor was demonstrated in each investigated membrane fraction with displacement experiments using (-)N-allyl-normetazocine as competitor of tritiated MERF. It was shown that this site was responsible for 60-80% of [3H]MERF binding. The remaining part of the naloxone resistant labelled MERF binding could be displaced only with endogenous opioid peptides as met-enkephalin, dynorphin and beta-endorphin. The eventual physiological role of multiple MERF receptors is discussed.     

Opioid receptor agonists in the rabbit colon: comparison of in vivo and in vitro studies

Myoelectrical activity was recorded in the proximal and distal colon of rabbits using chronically implanted electrodes. The motility in both the proximal and distal colon was inhibited by the intravenous (IV) administration of the following opioid agonists for mu receptors: morphine and fentanyl, kappa receptors: ethylketazocine (EKC) and U 50 488 H, and delta receptors: D-Ala2 D-Leu5-enkephalin (DADLE) and D-Ser2 Leu-enkephalin-Thr6 (DSLET). In contrast, the myoelectric activity in the distal colon was increased during the infusion of an endogenous kappa opioid agonist, dynorphin (DYN). All of these effects were prevented by naloxone pretreatment. During in vitro studies using extraluminal force transducers, fentanyl, U 50 488 H and DSLET inhibited spontaneous contractions of the proximal colon, but U 50 488 H and DSLET caused a substantial increase in the motility of the distal colon. The observed motor responses in the proximal and distal colon following opioid agonist administration indicate that the control of these two intestinal segments may be different. It is suggested that the stimulatory effect of dynorphin on the distal colon is peripherally-mediated while inhibition of the whole colon by opioid agonists regardless of subtypes seems to be centrally-mediated.     

Desipramine modulation of sigma and opioid peptide receptor expression in glial cells.

Exposure of C6 glial cell cultures to desipramine induced the appearance of opioid receptors and up-regulated sigma receptors. Opioid binding was demonstrated with 3H-etorphine and 3H-dihydromorphine (DHM), but was not observed with the mu, delta and kappa ligands 3H-DAMGE, 3H-DADLE or 3H-(-)ethylketocyclazocine in the presence of specific blockers, respectively. Competition experiments with 3H-DHM and either (-)naloxone or (+)naloxone indicated the presence of authentic opioid receptors. In similar studies with beta-endorphin, its truncated form (1-27) or their N-acetyl derivatives, beta-endorphin proved to have the highest affinity. Opioid receptors in glial cell aggregates were primarily kappa, with few mu and delta sites. Desipramine increased Bmax values for kappa but not mu and delta.     

Opioids and hibernation. II. Effects of kappa opioid U69593 on induction of hibernation in summer-active ground squirrels by "hibernation induction trigger" (HIT)

A "Hibernation Induction Trigger" (HIT) isolated from plasma of winter-hibernating woodchucks induced hibernation in summer-active ground squirrels (Citellus tridecemlineatus). Effects of kappa opioid U69593 on the HIT-induced hibernation were examined. U69593 alone did not elicit marked behavioral alteration or hibernation in summer-active ground squirrels. U69593, however, antagonized hibernation induced by HIT in summer active ground squirrels. In the guinea pig ileum myenteric plexus-longitudinal muscle preparation, woodchuck HIT depressed the electrically-induced contraction. The depression was, however, neither reversed nor blocked by naloxone even when naloxone was used at high doses. This study demonstrates that kappa opioid, at least in the case of U69593, was unable to induce hibernation in the summer-active ground squirrels. The results also demonstrate that woodchuck HIT, like the bear HIT, did not act directly at opioid receptors. Together with our previous observation that naloxone blocked summer hibernation induced by HIT (Bruce et al., Life Sci.., this issue), it is tempting to suggest that HIT may not mediate its effects through kappa opioid receptors but may do so through other types of opioid receptors such as mu or delta. U69593 may antagonize HIT-induced hibernation as a mu or delta receptor antagonist.     

Structural analysis of a rabbit immunoglobulin kappa 2 J-C locus reveals multiple deletions.

We previously reported that domestic rabbits harbor at least two DNA sequences that hybridize strongly to immunoglobulin kappa C region probes in Southern blots. One of these was cloned from a domestic b4 rabbit and identified as the gene for the nominal b4 allotype kappa chain which is expressed at high levels. We now have cloned (from a b4 rabbit) the other homologous sequence and find that it encodes a kappa chain nearly identical to the kappa 2 chain of "bas" rabbits, which is not normally expressed at detectable levels in domestic rabbits. Sequence analysis of this kappa 2 chain reveals a J kappa -C kappa locus with no obvious coding sequence defects that could explain its low expression. However, several base changes in a putative enhancer region as well as deletions (totalling about 1.5 kb) in the J-C intron might be related to low expression. The comparison between these two kappa genes raises questions about the selective pressures operating during the evolution of this gene system.     

Naloxone reduction of stress-related feeding

The effects of the narcotic antagonist, naloxone, on various types of stress- related feeding in rats were examined. Tail pinch-induced eating of a palatable substance, and 3 hr daytime rat chow intake following acute 2-deoxy-D-glucose (2-DG, 400 mg/kg) administration or 24 hr food deprivation were significantly decreased by low doses (1 mg/kg) of naloxone. Night time food intake was likewise decreased by naloxone (4 mg/kg). In contrast, hyperphagia induced by insulin (10 U/kg) was not decreased by naloxone (0.06–16 mg/kg). These findings suggest that narcotic antagonists should be considered as possible anorexics selective for stress-induced eating, and that endogenous opiates may prove to be another significant factor involved in the control of food intake.     

Effect of small doses of naloxone on sexual exhaustion in White New Zealand male rabbits

The objective of the present study was to determine the effect of small doses of naloxone on sexual exhaustion in White New Zealand male rabbits. Twelve young and 12 adult male rabbits 6–12 months old and 14–20 months of age, respectively, were selected from a commercial farm. Each male rabbit was housed individually in galvanized cages (90 cm × 60 cm × 40 cm). The rabbits were housed in an open shed exposed to natural photoperiod (12 L 12 D, 19°N). Daily temperature fluctuated through the year from 28 to 16 °C. Humidity was 45 ± 5%. Water and food (rabbit chow PMI) was supplied ad libitum. After sexual behaviour for each studied group was established, the males were given a 6-day rest, and 3 days before next trial, six males of each group (treated) received a subcutaneous implant of 8 mg of naloxone in a crystalline nitrocellulose pellet formulated to be completely absorbed in 15 days. The remaining six males were sham-treated (control). At the end of the resting period as previously described, the sexual behavior of each group was studied and compared using a Mann–Whitney statistical U-test. The effect of naloxone on sexual behavior was analyzed with a Wilcoxon test for correlated samples. With regard to sexual activity between young and adult rabbits, it was observed that there was a significant difference between groups (P = 0.00275, Z = 2.8823, adjusted Z = 2.99.43) showing that younger rabbits mounted/ejaculated from 9 to 10 females compared with 6 to 8 mounted/ejaculated by older rabbits. When naloxone was administered to both groups, there was a significant difference when comparing sexual behavior before and after administration of naloxone (table first and second trial). Young rabbits treated with naloxone mounted/ejaculated 11–12 females while older rabbits mounted nine females before reaching sexual exhaustion. A significant difference was observed when comparing the number of estrous females that were mounted/ejaculated between groups. Environmental photoperiod and temperature changes were not considered. It was concluded that endogenous opioids are important modulators of behavioral and hormonal interactions related to sexual behavior.     

Receptor-related interactions of opiates with PGE-induced adenylate cyclase in brain

The inhibition by opiates of the PGE2-induced formation of cAMP in slices from rat brain striatum was investigated. A maximal, 3.5-fold increase over the basal level of cAMP was obtained with an EC50 for PGE2 of 3 microM. Opiate agonists of both mu and kappa type were inhibitory. The IC50 values for morphine, levorphanol and ethylketocyclazocine (EKC) were 110 nM, 80 nM and 25 nM, respectively. These values were similar to the potencies of the compounds in displacing stereospecifically bound 3H-etorphine in rat brain membranes. As evidenced by the inactivity of dextrorphan, the inhibition of PGE2-dependent cAMP formation was stereospecific. Also ineffective were the opiate antagonists naloxone, naltrexone and MR 2266. These compounds did, however, reverse the inhibition by agonists, displaying thereby selectivity toward the putative mu and kappa opiates. Thus, the inhibition by morphine was antagonized to a greater degree by naloxone than by MR 2266, and the action of EKC was blocked more effectively by MR 2266 relative to naloxone.     

Suppression by naloxone of water intake induced by deprevation and hypertonic saline in intact and hypophysectomized rats

Naloxone, an opiate antagonist, was administered to intact and hypophysectomized male rats following hypertonic saline pretreatment or 12 hr water deprivation. Water intake following hypertonic saline or water deprevation was reduced by 0.01 – 10 mg/kg of naloxone in a dose-related fashion in both intact and hypophysectomized rats. Water consumption induced by hypertonic saline administration appeared to be more susceptible to the suppressant effects of naloxone than did that evoked by water deprevation. These results demonstrate that naloxone reduces water intake in the rat following intracellular dehydration by hypertonic saline administration, as well as after general dehydration induced by water deprevation. Furthermore, the suppressant effects of naloxone on water intake do not appear to involve pituitary endorphins, although a possible involvement of antidiuretic hormone in these effects cannot be excluded.