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Query: UMLS:C0020505 (
hyperphagia
)
6,116
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In a series of studies on histaminergic functions in the hypothalamus, probes to manipulate activities of histaminergic neuron systems were applied to assess its physiologic and pathophysiologic implications using non-obese normal and Zucker obese rats, an animal model of genetic obesity. Food intake is suppressed by either activation of H1-receptor or inhibition of the H3-receptor in the ventromedial hypothalamus (VMH) or the paraventricular nucleus, each of which is involved in satiety regulation.
Histamine
neurons in the mesencephalic trigeminal sensory nucleus modulate masticatory functions, particularly eating speed through the mesencephalic trigeminal motor nucleus, and activation of the histamine neurons in the VMH suppress intake volume of feeding at meals. Energy deficiency in the brain, i.e., intraneuronal glucoprivation, activates neuronal histamine in the hypothalamus. Such low energy intake in turn accelerates glycogenolysis in the astrocytes to prevent the brain from energy deficit. Thus, both mastication and low energy intake act as afferent signals for activation of histaminergic nerve systems in the hypothalamus and result in enhancement of satiation. There is a rationale for efficacy of a very-low-calorie conventional Japanese diet as a therapeutic tool for weight reduction. Feeding circadian rhythm is modulated by manipulation of hypothalamic histamine neurons. Hypothalamic histamine neurons are activated by an increase in ambient temperature. Hypothalamic neuronal histamine controls adaptive behavior including a decrease in food intake and ambulation, and an increase in water intake to maintain body temperature to be normally constant. In addition, interleukin-1 beta, an endogenous pyrogen, enhanced turnover of neuronal histamine through prostaglandin E2 in the brain. Taken together, the histamine neuron system in the hypothalamus is essential for maintenance of thermoregulation through the direct and indirect control of adaptive behavior. Behavioral and metabolic abnormalities of obese Zucker rats including
hyperphagia
, disruption of feeding circadian rhythm, hyperlipidemia, hyperinsulinemia, and disturbance of thermoregulation are essentially derived from a defect in hypothalamic neuronal histamine. Abnormalities produced by depletion of neuronal histamine from the hypothalamus in normal rats mimic those of obese Zuckers. Grafting the lean Zucker fetal hypothalamus into the obese Zucker pups attenuates those abnormalities. These findings indicate that histamine nerve systems in the brain play a crucial role in maintaining homeostatic energy balance.
...
PMID:Hypothalamic neuronal histamine: implications of its homeostatic control of energy metabolism. 922 31
Histamine
H(1) receptors (H(1)-Rs) are found in peripheral tissues and in regions of the hypothalamus that are concerned with regulating body composition. In the present study, we investigated the detailed mechanisms of histamine H(1)-Rs in the development of obesity.
Histamine
H(1)-R knockout (H1KO) mice gradually developed mature-onset obesity, which was accompanied by
hyperphagia
and decreased expression of uncoupling protein-1 (UCP-1) mRNA. Both younger nonobese (12-week-old) and older obese (48-week-old) H1KO mice exhibited impairment of the responsiveness to the leptin. In addition, disruption of the diurnal rhythm of feeding occurred before the onset of obesity in H1KO mice. Correction of these abnormal feeding rhythms by means of scheduled feeding caused a reduction in obesity and associated metabolic disorders in H1KO mice. Furthermore, central administration of a histamine H(1)-R agonist affected feeding behavior, body weight, and c-fos-like immunoreactivity in the hypothalamus. Taken together, these findings suggest that histamine H(1)-Rs are crucial for the regulation of feeding rhythm and in mediating the effects of leptin. Early disruption of H(1)-R-mediated functions in H1KO mice may lead to
hyperphagia
and decreased expression of UCP-1 mRNA, which may contribute to the development of obesity in these animals. In addition, centrally acting histamine H(1)-R may be a novel therapeutic target for the treatment of obesity and related metabolic disorders.
...
PMID:Involvement of hypothalamic histamine H1 receptor in the regulation of feeding rhythm and obesity. 1533 34
Histamine
H3 receptors (H3Rs) are autoreceptors that negatively regulate the release of histamine and other neurotransmitters such as norepinephrine, dopamine, and acetylcholine in the central nervous system (CNS). Consistent with the wide-spread projection of histaminergic neurons from the lateral hypothalamus, H3Rs are widely distributed in the CNS and are believed to play a variety of physiological roles, including regulation of feeding, arousal, cognition, pain, and endocrine systems. To further understand the physiological roles of H3Rs in vivo, we produced H3R knockout (H3R-/-) mice and found that H3R-/- mice displayed
hyperphagia
and late-onset obesity associated with hyperinsulinemia and leptinemia, the fundamental marks of metabolic syndromes. A series of non-imidazole H3R antagonists/inverse agonists with improved selectivity and potency have been developed and were found to regulate feeding and body weight gain in laboratory animals. Taken together, these observations suggest that H3Rs are involved in the regulation of feeding behavior and body weight. Several H3R inverse agonists targeting cognitive disorders and dementia have entered clinical trials. These trials will give critical information about the physiological functions of H3Rs in humans.
...
PMID:Recent advances in molecular pharmacology of the histamine systems: physiology and pharmacology of histamine H3 receptor: roles in feeding regulation and therapeutic potential for metabolic disorders. 1664 67
The hypothalamic arcuate, dorsomedial and paraventricular nuclei are involved in regulation of body weight and food intake and contain binding sites for the anorexigenic amylin. Effects of amylin on medial arcuate and paraventricular neurons studied in adult rats overweight through early postnatal overfeeding in small litters (SL) differed from those of control litters (CL). Now we observed that also dorsomedial neurons respond differentially to this satiety signal. They were significantly inhibited by amylin in SL but not CL rats. Since the histaminergic system seems to be involved in mediating effects of amylin, we studied the role of histamine H(1)-receptors. Single unit activity was recorded in brain slices of CL and SL rats in each of the three hypothalamic nuclei. The histamine H(1)-receptor antagonist pyrilamine differentially altered or reduced responses to amylin, not depending on the kind of litter but on the functional effect of the peptide. Pyrilamine prevented significant inhibition of medial arcuate neurons in controls as well as inhibition of dorsomedial and paraventricular neurons in SL rats. Searching for further mechanisms possibly contributing to the change of neuronal responses we found that in the presence of a GABA(A)-receptor antagonist amylin induced a significant inhibition of medial arcuate neurons in SL rats similar to that in CL without antagonist. Activation of medial arcuate neurons expressing the orexigenic neuropeptide Y and inhibition of dorsomedial and paraventricular neurons in SL rats may in vivo contribute to
hyperphagia
and overweight.
Histamine
H(1)-receptors and GABA(A)-receptors seem to be differentially involved in mediation of these effects.
...
PMID:Histamine H1-receptors differentially mediate the action of amylin on hypothalamic neurons in control and in overweight rats. 1758 64
