UMLS:C0020505 - FACTA Search

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Query: UMLS:C0020505 (hyperphagia)
6,116 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Disturbances in hypothalamic beta-endorphin and dynorphin levels were investigated in non-fasted genetically obese (ob/ob) and homozygous lean mice at 14-15 weeks of age. Eight brain regions were microdissected from fresh, unfixed brain slices, and opioid peptide concentrations were determined in tissue micropunches by radioimmunoassay. A two-fold and five-fold increase in beta-endorphin levels in ob/ob versus lean mice were found in the ventromedial and dorsomedial hypothalamic nuclei respectively. Dynorphin levels were comparable between ob/ob and lean mice in the anterior, lateral, ventromedial and paraventricular hypothalamic areas, but a 5-fold increase in dynorphin concentrations was detected in the dorsomedial hypothalamic nucleus of the ob/ob mouse. These results demonstrate that increased concentrations of beta-endorphin and dynorphin occur in discrete hypothalamic nuclei, which are known to influence food intake and glucose homeostasis. This could signify an important central defect contributing to hyperphagia and glucoregulatory dysfunction in obese mice.
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PMID:Increased beta-endorphin and dynorphin concentrations in discrete hypothalamic regions of genetically obese (ob/ob) mice. 168 94

The equilibrium dissociation constants and maximal binding capacities of 3H-dihydromorphine (DHM), 3H-D-Ala2-D-leu3-enkephalin (DADL), and 3H-dynorphin A(1-8) for their respective mu, delta, and kappa opiate binding sites were studied in brain membrane preparations from lean and genetically obese-hyperglycaemic (Aston ob/ob) mice. The concentration of kappa binding sites was 2.7 fold higher in obese compared with lean mouse brain (231 +/- 44.6 versus 83.8 +/- 10.3 fmoles 3H-dynorphin/mg protein respectively, mean +/- SEM). The concentration of delta binding sites in obese was 1.6 fold that in lean mouse brain (94.5 +/- 8.6 versus 59.5 +/- 6.5 fmoles 3H-DADL/mg protein). In contrast, the concentration of brain mu receptors was 40% lower in obese compared with lean mice (20.8 +/- 2.19 and 34.8 +/- 3.1 fmoles 3H-DHM/mg protein respectively). Binding affinities of delta and kappa sites for their respective ligands were not significantly different in lean v. obese mice. However, for mu sites, lean mouse binding data showed two affinities, one was not significantly different from obese (0.35 nM) the second was lower (1.18 nM) for DHM. Increases of approximately 5 fold and 3 fold in the brain content of beta-endorphin and met-enkephalin respectively, and no differences in brain dynorphin levels, were demonstrated in obese mice compared with lean controls. In obese mice, pituitary beta-endorphin content was 9 fold higher, met-enkephalin 4 fold higher and dynorphin 12 fold higher than in lean mice. The striking differences in opioid binding-site characteristics and in endogenous opioid peptide levels in obese compared with lean mice may contribute to the hyperphagia and, directly or indirectly, to the development of hyperglycaemia and hyperinsulinaemia in obese mice.
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PMID:Central mu, delta, and kappa opioid binding sites, and brain and pituitary beta-endorphin and met-enkephalin in genetically obese (ob/ob) and lean mice. 252 15

It has been suggested that super-sensitivity to, or overactivity of, endogenous opioid systems, particularly the dynorphin system, may be important in the development of obesity in the obese mouse (ob/ob). We have investigated the possibility that an increase in sensitivity to kappa agonists may also play a role in the development of obesity in another mutant rodent, the Zucker rat. The effects of the selective kappa agonist PD-117302 were investigated in both lean and obese Zucker rats. The lean animals appeared to be more sensitive to the initial hyperphagic effects of PD-117302 than their obese littermates, although this initial hyperphagia was followed by a subsequent decrease in food intake so that by the end of the six-hour test period the animals treated with PD-117302 had eaten less than the saline-treated controls. These changes in food intake were paralleled by increases and decreases in the duration of time spent feeding throughout the experiment. At the doses used in this study PD-117302 had no effect on locomotor activity. It is concluded that obese Zucker rats are not more sensitive to the hyperphagic effects of the kappa agonist (PD-117302 than their lean littermates and therefore it seems unlikely that increased sensitivity to an endogenous kappa opioid system plays a major part in the overeating and obesity observed in this strain of rat.
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PMID:The effects of the kappa agonist PD-117302 on feeding behaviour in obese and lean Zucker rats. 285 65

Dynorphin is one of the most potent appetite stimulants among the endogenous opioids. In this study, we describe the anorexic effects of 5 days of forced 2% NaCl drinking in rats, a regimen which depletes vasopressin as well as dynorphin in the neurohypophysis. Feeding induced by direct activation of kappa-opioid receptors with ketocyclazocine was unaffected by the NaCl regimen. However, 2% NaCl imbibition reduced 2-deoxy-D-glucose (2-DG) induced feeding by 65% and spontaneous nocturnal feeding by 38%. Feeding subsequent to 24 hour food deprivation was not decreased. Naloxone-resistant hyperphagia induced by insulin and spontaneous daytime feeding were also not reduced. The combination of naloxone (3.0 mg/kg) and the NaCl regimen produced an additional 50% reduction in 2-DG induced feeding and an extra 40% decrease in nocturnal feeding. Naloxone, given with 2% NaCl to food deprived animals, retained its appetite suppressing activity, indicating that the NaCl regimen did not deplete the endogenous opioid which mediates food deprivation hyperphagia. These results demonstrate that 2% NaCl imbibition suppresses certain opioid mediated hyperphagias. However, the failure of 2% NaCl to affect all of the naloxone-sensitive types of feeding and the independence of naloxone-sensitive and NaCl-sensitive components suggests that NaCl drinking does not deplete dynorphin in the brain areas which mediate opiate-sensitive hyperphagias.
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PMID:Effects of 2% sodium chloride imbibition on various opiate related hyperphagic conditions. 286 2

Evidence from studies which utilise either opiate receptor agonists and antagonists strongly indicate a role for endorphinergic mechanisms in the control of feeding responses. Two means by which these compounds may exert an effect on feeding can be singled-out. Firstly, emerging evidence suggests that the process of achieving satiety (terminating a meal, or choice of a commodity) may be accelerated following treatments with opiate receptor antagonists. Secondly, the preference for highly palatable solutions (sweet solutions have received most attention) in two-bottle tests is blocked after injection of opiate receptor antagonists. This finding has been interpreted in terms of the abolition of the reward or incentive quality associated with the particularly attractive flavour. These two mechanisms of action may represent two aspects of a single, fundamental process. Following an introduction to rat urination model of in vivo kappa agonist activity, the consistent effect of several kappa agonists (including the highly selective U-50,488H) to stimulate food consumption is described. Recognising that members of the dynorphin group of endogenous opioid peptides are kappa receptor ligands, some with a high degree of selectivity, and the evidence the dynorphins and neo-endorphins produce hyperphagia in rats is particularly interesting. Such lines of evidence lead to the hypothesis that peptides of the dynorphin group may act endogenously to promote the expression of normal feeding behaviour.
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PMID:Endorphins and food intake: kappa opioid receptor agonists and hyperphagia. 286 62

Bilateral, radiofrequency lesions of the mediobasal arcuate hypothalamus (MBH) strongly depleted levels of immunoreactive (ir)-beta-endorphin (beta-EP) in the hypothalamus and other brain tissues: these changes reflect destruction of those beta-EP-containing perikarya which are located in the MBH. No change in plasma ir-beta-EP was seen. The ir-dynorphin (DYN) content of the hypothalamus was also depressed while that of ir-Met-enkephalin was unaffected. The fall in hypothalamic ir-beta-EP was correlated with the fall in that of ir-DYN. Lesioned rats displayed only a minor, transient reduction in rate of weight gain between days 3 and 9 postsurgery: this disappeared thereafter. Further, the lesion did not affect the pattern of weight loss and regain associated with 24 h food and water deprivation. Indeed, the total 24 h (daily) food intake (FI) and water intake (WI) of lesioned rats did not differ from that of sham animals while deprivation-induced hyperphagia and hyperdipsia was not attenuated by the lesions. Moreover, the ability of naltrexone to decrease FI and WI (during both dark and light phases of the daily cycle) was not altered by the lesions. These observations indicate that central beta-EP may not be essential for the maintenance of a normal 24 h FI and WI and that opioid antagonists do not act upon the MBH or upon central beta-EP neurones in their suppression of FI and WI. Further, they suggest that central beta-EP may not fulfil an essential role in the control of body weight in the rat. Lesioned rats did, however, reveal a shift in the diurnal rhythmicity of FI and WI reflected in a reduction in the dark:light ratios of these. An alteration in the diurnal rhythmicity of sleeping and core temperature, but not locomotor activity, was also seen. The shifts in hypothalamic ir-beta-EP and ir-DYN (but no other tissue levels of any peptide) were correlated with the magnitude of the shifts in diurnal rhythmicity of ingestive behaviour. Moreover, lesions caudal to the MBH (not affecting hypothalamic ir-beta-EP or ir-DYN) or dexamethasone treatment (which affects pituitary pools of ir-beta-EP and ir-DYN) did not modify these rhythms. Thus, in these respects, the effects are 'particular' to MBH lesions modifying hypothalamic ir-beta-EP and ir-DYN. The data suggest that the MBH may play a role in the modulation of the diurnal scheduling of ingestive behaviour in the rat.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The role of the mediobasal arcuate hypothalamus in relation to opioid systems in the control of ingestive behaviour in the rat. 287 65

The high-affinity mu-1 opioid binding site has been implicated in some opioid responses (e.g., supraspinal analgesia) but not others (e.g., respiratory depression) by comparing the actions of naloxone, a short-acting, non-selective antagonist, and naloxonazine, an irreversible and selective mu-1 antagonist. The mu-1 site has been implicated in the opioid component modulating free feeding and deprivation-induced feeding, but not glucoprivic feeding. The present study compared naloxone and naloxonazine antagonism of hyperphagia induced by morphine, ethylketocyclazocine (EKC), dynorphin and d-ala2,d-leu5-enkephalin (DADL) in rats. Morphine produced a dose-dependent (0.01-5 mg/kg) hyperphagia in mildly food-deprived rats that was blocked by naloxone (0.01-10 mg/kg). Naloxonazine (10 mg/kg) shifted the morphine hyperphagia dose-response curve to the right. These effects could not be fully accounted for by the intrinsic hypophagic properties of these antagonists. EKC produced a dose-dependent (0.5-5 mg/kg) hyperphagia which was blocked by naloxone (10 mg/kg) only at low effective EKC doses. Naloxonazine (10 mg/kg) failed to affect EKC hyperphagia. Naloxone, but not naloxonazine also blocked dynorphin and DADL hyperphagia. These results indicate that feeding induced by opiate and opioid agonists are differentially mediated by the mu-1 and other opioid binding sites; these data contrast with the modulation by the mu-1 site of the supraspinal analgesia induced by each of these agonists.
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PMID:Differential sensitivity of opioid-induced feeding to naloxone and naloxonazine. 289 39

A comparison of the effects of the short-acting opioid antagonist naloxone, with the irreversible and highly-specific mu-1 antagonist naloxonazine, has categorized the mediation of opioids in some forms of feeding into mu-1 and non-mu-1 components. The mu-1 sites have been implicated in free-feeding, deprivation-induced feeding and morphine-induced hyperphagia, based upon their sensitivity to both naloxone and naloxonazine. However, the ability of naloxone, but not naloxonazine to inhibit feeding, induced by either 2-deoxy-D-glucose glucoprivation, ethylketocyclazocine, dynorphin or (D-ala2., D-leu5.)-enkephalin implies the existence of non-mu-1 opioid receptor mechanisms in these responses. The present study compared the effects of the daily administration of naloxone and naloxonazine (10 mg/kg, i.v.) in rats in three different types of maturational or dietary situations. In adult rats, naloxonazine and naloxone significantly reduced body weight (7% and 4%, respectively) and food intake (21% and 13%, respectively) over 14 days. These effects were more pronounced in adolescent rats where naloxonazine and naloxone significantly reduced the gain in body-weight (53% and 33%, respectively) and food intake (24% and 15%, respectively) over 14 days. In the adolescent rats, the effects of naloxonazine were significantly greater than those of naloxone. In contrast, chronic treatment with neither naloxone nor naloxonazine altered body weight or food intake of rats made obese by dietary manipulations and left on that diet during treatment with antagonist.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Comparison of effects of chronic administration of naloxone and naloxonazine upon food intake and maintainance of body weight in rats. 341 36

Opiate receptor blockade, or forced imbibition of 2% NaCl to deplete pituitary dynorphin decreases 2-deoxy-D-glucose (2-DG), but not insulin-induced hyperphagia, indicating a possible role for dynorphin in the eating associated with endogenous opiates. Beta-adrenergic receptor blockade decreases vasopressin release induced by 2-DG but not by insulin. Because vasopressin and dynorphin are sometimes co-localized, it was hypothesized that naloxone-sensitive feeding might be selectively inhibited by beta-adrenergic blockade with propranolol. Propranolol in doses as low as 2.5 mg/kg inhibited 4 hr feeding induced by 2-DG (400 mg/kg). Propranolol did not significantly affect feeding induced by ketocyclazocine administration (3.0 mg/kg) or by 24 hr food deprivation. Feeding stimulated by insulin (10 U/kg) was significantly inhibited by propranolol (2.5 mg/kg) only when the propranolol was reinjected during the period 2 hr after insulin injection, when the induced feeding was greatest. In summary, propranolol inhibited opiate-related (2-DG) as well as opiate-independent (insulin) hyperphagias. It also failed to inhibit food intake resulting from the opiate related stimulus of 24 hr food deprivation. Therefore, naloxone sensitive hyperphagias were not specifically inhibited by beta-adrenergic blockade, indicating that vasopressin-associated dynorphin is not involved in opiate related feeding.
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PMID:Differential inhibition by propranolol of feeding induced in rats by various stimuli. 609 26

Modulation of feeding by opiates, putative satiety peptides, and dopamine was explored in the Chinese hamster, an animal that develops diabetes mellitus in certain inbred strains. Diabetic hamsters were hyperphagic relative to their nondiabetic controls, but both groups exhibited natural circadian variation in feeding. Starvation provoked hyperphagia of about 1-h duration in both groups. Naloxone and butorphanol had no effects on Chinese hamster feeding. Opiate receptor binding on Chinese hamster brains demonstrated no specific binding of naloxone or ethylketocyclazocine, but IR-dynorphin concentrations were comparable with that in rats. N-allylnormetazocine, a sigma-opiate receptor agonist, appeared to stimulate diabetic hamster feeding. Peptides reputed to have satiety effects in rats were without effect in Chinese hamsters: cholecystokinin, bombesin, somatostatin, and pancreatic polypeptide. Calcitonin limited feeding in both groups but may be nonspecific. Dopaminergic blockade by haloperidol also limited feeding, and diabetic hamsters were more sensitive to this. Although Chinese hamsters clearly can modulate their food intake when diabetic, we conclude that the opiatergic and peptidergic influences on feeding are very different from those in rats and may be of little importance.
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PMID:Feeding systems in Chinese hamsters. 614 21

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