5-HT1B receptors modulate the feeding inhibitory effects of enterostatin

Serotonin (5-HT) is considered to play an important role in control of appetite. Enterostatin has been shown to alter 5-HT release in the brain, and non-specific 5-HT antagonists blocked the anorectic response to icv enterostatin. The aim of this study was to further identify which 5-HT receptor subtype mediates the enterostatin feeding behavior and whether this effect occurs due to action in the PVN. Wild-type and 5-HT2C receptor-/- (KO) mice and normal Sprague-Dawley rats were used in these experiments. All animals were fed a high fat diet. Enterostatin (120 nmol, i.p.) reduced the intake of high fat diet in 5-HT2C receptor mutant mice (saline 4.54 +/- 0.47 kcal vs. Ent 2.53 +/- 0.76 kcal) 1 h after injection. A selective 5-HT1B antagonist (GR55526, 40 mg/kg body weight, i.p.) blocked the enterostatin hypophagic effects in these KO mice. Rats were implanted with cannulas into the amygdala and the ipsilateral PVN. The 5-HT receptor antagonists metergoline (non-specific receptor subtypes 1 and 2), or ritanserin (selective 2C), or GR55562 (selective l B) was injected into the PVN prior to enterostatin (0.01 nmol) injection into the amygdala. Enterostatin reduced food intake (saline: 5.80 +/- 0.59 g vs. enterostatin 3.47 +/- 0.56 g, P < 0.05 at l h). Pretreatment with either metergoline (10 nmol) or GR55526 (10 nmol) but not ritanserin (10 nmol) into the PVN attenuated the anorectic response to amygdala enterostatin. The data imply that the enterostatin anorectic response may be modulated by 5-HT1B receptors and that a neuronal pathway from the amygdala to the PVN regulates the enterostatin response through activation of 5-HTlB receptors in PVN.     

The role of enterostatin and apolipoprotein AIV on the control of food intake

Procolipase is secreted as a protein consisting of 101 amino acids. In the intestinal lumen, procolipase is activated by trypsin and cleaves to form the active colipase and the pentapeptide from the amino terminus. This pentapeptide is called enterostatin. Pancreatic procolipase synthesis is stimulated by a high-fat diet. A large body of evidence has been gathered in the past decade demonstrating the role of enterostatin in the inhibition of food intake; in particular, fat intake. This aspect of enterostatin will be discussed in this review. Other functions of enterostatin such as the inhibition of insulin secretion, will not. Apolipoprotein AIV is a protein synthesized by the human intestine. Similar to procolipase, the synthesis and secretion of apo AIV are also stimulated by fat absorption. In 1992, Fujimoto et al. first demonstrated that apo AIV is a satiety signal secreted by the small intestine following the ingestion of a lipid meal. Subsequently, this initial observation was followed by a number of studies supporting apo AIV's role in the inhibition of food intake. This review will discuss the role of apo AIV in inhibiting food intake.     

Amygdala enterostatin induces c-Fos expression in regions of hypothalamus that innervate the PVN

Enterostatin selectively inhibits the intake of the dietary fat after both central and peripheral administration. Our previous studies have shown that a central site of action is the central nucleus of amygdala. Serotonergic agonists administered into the paraventricular nucleus (PVN) inhibit fat intake and serotonergic antagonists block the feeding suppression induced by amygdala enterostatin, suggesting that there are functional connections between the PVN and amygdala that affect the feeding response to enterostatin. Our purpose was to identify the anatomic and functional projections from the amygdala to the PVN and hypothalamic area that are responsive to enterostatin, by using a retrograde tracer fluorogold (FG) and c-Fos expression. Rats were injected with fluorogold unilaterally into the PVN and a chronic amygdala cannula was implanted ipsilaterally. After 10 days recovery, rats were injected with either enterostatin (0.1 nmol) or saline vehicle (0.1 microl) into the amygdala and sacrificed 2 h later by cardiac perfusion under anesthesia. The brains were subjected to dual immunohistochemistry to visualize both FG and c-Fos-positive cells. FG/c-Fos double-labeled cells were found in forebrain regions including the PVN, amygdala, lateral hypothalamus (LH), ventral medial hypothalamus (VMH) and arcuate nucleus (ARC). The data provides the first anatomical evidence that enterostatin activates amygdala neurons that have functional and anatomic projections directly to the PVN and also activates neurons in the arcuate, LH and VMH, which innervate the PVN.     

Intra-amygdalar injection of DAMGO: effects on c-Fos levels in brain sites associated with feeding behavior

It is well known that the mu opioid agonist, Tyr-D-Ala-Gly-(me) Phe-Gly-ol (DAMGO), increases food intake in rats when injected into a variety of brain sites including the central nucleus of the amygdala (CeA). Immunohistochemical studies measuring c-Fos immunoreactivity (IR) suggest that the CeA contributes to opioid-related feeding. In the current study, we injected 2 nmol of DAMGO and measured food intake, c-Fos IR levels in various brain sites involved in feeding behavior, and mu opioid receptor internalization. We also studied the effect of CeA-injected DAMGO on LiCl-induced increases in c-Fos IR in the amygdala. As was expected, intra-CeA injection of DAMGO increased food intake of rats over a 4-h period. DAMGO injection into the CeA also resulted in mu opioid receptor internalization in the CeA, indicating activation of mu opioid receptor expressing neurons in this site. Administration of DAMGO into the CeA increased c-Fos IR levels in the shell of the nucleus accumbens (NAcc), but not in 17 other brain sites that were studied. We also found that intra-CeA injection of DAMGO, prior to LiCl injection, decreased c-Fos IR levels in the CeA compared to vehicle-injected rats. Thus, intra-CeA administration of DAMGO may increase feeding, in part, by activating neurons in the shell of the nucleus accumbens and by inhibiting activity of selected neurons in the CeA.     

Extensive brain mapping of calcitonin-induced anorexia

The purpose of this study was to compare the localization in the brain of calcitonin-induced anorexia to the distribution of calcitonin binding sites (as described by others). We, thus, performed an extensive mapping of brain structures to determine those involved in calcitonin-induced anorexia. A significant anorexia is found after injection of calcitonin (15 ng in 0.3 μl) into several brain areas. Forebrain: lateral septum, lateral part of the anterior commissure, and bed nucleus of the stria terminalis; hypothalamus: floor of the anterior part of the hypothalamus, paraventricular nucleus and adjacent perifornical area; thalamus: nucleus reuniens, an area internal to the mamillo-thalamic tract, and medial geniculate body; other areas: amygdala, lateral hippocampus, and central gray. No significant effect is found in the following areas: forebrain: nucleus accumbens, striatum, and medial septum; hypothalamus: lateral, ventro-medial, dorso-medial, and posterior nuclei; thalamus: centro-medial nucleus, lateral part of the zona incerta, and lateral geniculate body; hippocampus: dorsal and ventral parts; midbrain: central tegmentum, ventral tegmental area, and substantia nigra. When these results are compared to the distribution of calcitonin binding sites in the brain, two types of discrepancies are found. The first is the absence of effect in areas containing receptors: these areas may be involved in calcitonin-induced behaviors other than food intake. The second is the occurence of anorexia in areas where no receptors are found: this finding is not easy to explain and raises some speculative hypotheses. In conclusion, calcitonin is active to decrease food intake in several brain areas, the strongest effect occurring in the paraventricular/perifornical area. This is consistent with other evidence from the literature supporting a role of this area in the control of food intake. The reason why calcitonin also acts in areas not known to be involved in food intake and devoid of calcitonin receptors, as well as the mechanism by which calcitonin inhibits feeding, remains to be investigated.     

Fos expression in feeding-related brain areas following intracerebroventricular administration of orphanin FQ in rats

While the influence of orphanin FQ (OFQ) on the regulation of food intake has been substantiated, little is known about feeding-related brain regions that mediate OFQ-induced feeding. To further investigate this, we injected OFQ intracerebroventricularly and evaluated c-Fos immunoreactivity in brain areas thought to be involved in the regulation of food intake. Altered c-Fos expression as a consequence of OFQ injection was observed in the nucleus of the solitary tract, paraventricular nucleus of the hypothalamus, supraoptic nucleus, central nucleus of amygdala, lateral septal nucleus and lateral habenular nucleus. Presumably, OFQ modulates food ingestion through its action on these brain regions, most probably by activating feeding signals as well as suppressing satiety mechanisms.     

Differential effects of enterostatin, galanin and opioids on high-fat diet consumption

Enterostatin, the activation peptide of pancreatic procolipase, suppresses high-fat diet consumption both centrally and peripherally. κ-opioid agonists are also known to stimulate fat intake. These experiments were conducted to determine if an opioidergic central pathway might mediate the effects of enterostatin and galanin on fat intake. Male Sprague-Dawley rats were adapted to a high-fat diet (56% energy) and were implanted with cannulae aimed at the lateral cerebral ventricle (LV) or third cerebral ventricle (3V). Injection of enterostatin (1 nmol, LV) suppressed high-fat diet consumption in fasted (20 h) rats. This inhibition of high-fat intake by enterostatin was attenuated by central injection of the specific κ-agonist U50488 (2.15, 21.5 and 215 nmol, LV) in a dose-dependent manner in fasted rats while only the highest dose of U50488 (215 nmol, LV) independently produced stimulation of high-fat diet consumption in sated rats. Galanin (0.1 nmol, 3V) induced consumption of high-fat diet in sated rats similar to that seen with U50488 and this stimulation was attenuated by peripheral injection of naloxone (1.0 mg/kg i.p.). We present a model which integrates the present data, as well as previous findings, in explaining a potential common opioid pathway modulating fat consumption.     

Enterostatin suppresses food intake following injection into the third ventricle of rats

The effect on food intake of an activation peptide from pancreatic pro-colipase, called enterostatin, has been studied after parenteral or third ventricular administration. The activation peptide (enterostatin = Val-Pro-Asp-Pro-Arg = VPDPR) reduced food intake when given intraperitoneally. Low doses of this peptide also reduced food intake when given into the third ventricle, but high doses were ineffective. Enterostatin did not modify the stimulatory effects on food intake of clonidine, an alpha 2-adrenergic agonist, suggesting that its anorectic effects are not mediated via the alpha 2-adrenergic system. These data suggest that enterostatin, an activation peptide from pro-colipase, may play a role in producing satiety.     

瘦素受体在大鼠脑的免疫组织化学定位研究

观察瘦素受体在SD大鼠脑的组织学定位。采用高度特异的抗瘦素受体血清 ,用免疫组织化学ABC法观察瘦素受体在大鼠脑的分布。结果表明 :在SD大鼠的前脑 (包括嗅球 )、皮质Ⅳ～Ⅴ层、海马、下丘脑、杏仁核、丘脑等可以观察到瘦素受体免疫反应阳性物质 (LR IR) ,其中下丘脑弓状核、视上核、视交叉上核、杏仁基底外侧核、孤束核有较强的LR IR ,而下丘脑外侧视前区、杏仁中央核有较弱的LR IR。提示 :瘦素受体广泛存在于大鼠脑 ,包括下丘脑、杏仁核等与味觉和摄食调节密切相关的核团     

Expression of a novel neuropeptide Y receptor subtype involved in food intake: an in situ hybridization study of Y5 mRNA distribution in rat brain

Our group has reported on the cloning of a novel rat neuropeptide Y (NPY) receptor involved in NPY-induced food intake, the Y5 receptor. The distribution in rat brain of the mRNA encoding this receptor has been determined by in situ hybridization histochemistry, using radiolabeled oligonucleotide probes. Control experiments were carried out in cell lines transfected with either rat Y1 or rat Y5 cDNAs. With the exception of the cerebellum, only the antisense probes yielded hybridization signal in rat brain tissue sections. A number of brain regions contained hybridization signals indicative of Y5 mRNA localization. Chief among these were various hypothalamic nuclei, including the medial preoptic nucleus, the supraoptic nucleus, the paraventricular nucleus, and the lateral hypothalamus. Other regions with substantial hybridization signals included the midline thalamus, parts of the amygdala and hippocampus, and some midbrain and brain-stem nuclei. In general a low density of Y5 mRNA was observed in most cortical structures, with the exception of the cingulate and retrosplenial cortices, each of which contained a moderate abundance of Y5 hybridization signal. The distribution of this receptor mRNA is consistent with a role for the Y5 receptor in food intake and also suggests involvement in other processes mediated by NPY.     

Localization of the urotensin II receptor in the rat central nervous system

The vasoactive peptide urotensin II (UII) is primarily expressed in motoneurons of the brainstem and spinal cord. Intracerebroventricular injection of UII provokes various behavioral, cardiovascular, motor, and endocrine responses in the rat, but the distribution of the UII receptor in the central nervous system (CNS) has not yet been determined. In the present study, we have investigated the localization of UII receptor (GPR14) mRNA and UII binding sites in the rat CNS. RT-PCR analysis revealed that the highest density of GPR14 mRNA occurred in the pontine nuclei. In situ hybridization histochemistry showed that the GPR14 gene is widely expressed in the brain and spinal cord. In particular, a strong hybridization signal was observed in the olfactory system, hippocampus, olfactory and medial amygdala, hypothalamus, epithalamus, several tegmental nuclei, locus coeruleus, pontine nuclei, motor nuclei, nucleus of the solitary tract, dorsal motor nucleus of the vagus, inferior olive, cerebellum, and spinal cord. Autoradiographic labeling of brain slices with radioiodinated UII showed the presence of UII-binding sites in the lateral septum, bed nucleus of the stria terminalis, medial amygdaloid nucleus, anteroventral thalamus, anterior pretectal nucleus, pedunculopontine tegmental nucleus, pontine nuclei, geniculate nuclei, parabigeminal nucleus, dorsal endopiriform nucleus, and cerebellar cortex. Intense expression of the GPR14 gene in some hypothalamic nuclei (supraoptic, paraventricular, ventromedian, and arcuate nuclei), in limbic structures (amygdala and hippocampus), in medullary nuclei (solitary tract, dorsal motor nucleus of the vagus), and in motor control regions (cerebral and cerebellar cortex, substantia nigra, pontine nuclei) provides the anatomical substrate for the central effects of UII on behavioral, cardiovascular, neuroendocrine, and motor functions. The occurrence of GPR14 mRNA in cranial and spinal motoneurons is consistent with the reported autocrine/paracrine action of UII on motoneurons.     

Distribution of Fos-like immunoreactivity within the rat brain following intraventricular injection of the selective NK(3) receptor agonist senktide

Neurokinin B (NKB) is one member of an evolutionarily conserved family of neuropeptides, the tachykinins. Preferential binding of NKB to endogenous NK(3) receptors affects a variety of biological and physiological processes, including endocrine secretions, sensory transmission, and fluid and electrolyte homeostasis. In light of its widespread biological actions, immunohistochemical detection of the c-Fos protein product was used to study the distribution of neuronal activation in the rat brain caused by intraventricular (icv) injections of the selective NK(3) receptor agonist (succinyl-[Asp(6), N-Me-Phe(8)] substance P [6-11]), senktide. Quantitative analysis revealed that treatment with isotonic saline or 200 ng senktide resulted in the differential expression of Fos-like immunoreactivity (FLI) throughout the brain. Senktide induced the highest number of FLI neurons in the lateral septum, bed nucleus of the stria terminalis, amygdala, paraventricular nucleus of the hypothalamus, median preoptic nucleus, organum vasculosum of the lamina terminalis, supraoptic nucleus, periaqueductal gray, and medial nucleus of the solitary tract compared to isotonic saline controls. Additional regions that contained elevated FLI following icv injection of senktide, relative to saline injection, included the cerebral cortex, lateral hypothalamic nucleus, suprachiasmatic nucleus, ventral tegmental area, substantia nigra, inferior colliculus, locus coeruleus, zona incerta, and arcuate nucleus. Our data indicate that activation of NK(3) receptors induces the expression of FLI within circumscribed regions of the rat brain. This pattern of neuronal activation overlaps with nuclei known to regulate homeostatic processes, such as endocrine secretion, cardiovascular function, salt intake, and nociception.     

Expression of prokineticins and their receptors in the adult mouse brain

Prokineticins are a pair of regulatory peptides that have been shown to play important roles in gastrointestinal motility, angiogenesis, circadian rhythms, and, recently, olfactory bulb neurogenesis. Prokineticins exert their functions via activation of two closely related G-protein-coupled receptors. Here we report a comprehensive mRNA distribution for both prokineticins (PK1 and PK2) and their receptors (PKR1 and PKR2) in the adult mouse brain with the use of in situ hybridization. PK2 mRNA is expressed in discrete regions of the brain, including suprachiasmatic nucleus, islands of Calleja and medial preoptic area, olfactory bulb, nucleus accumbens shell, hypothalamic arcuate nucleus, and amygdala. PK1 mRNA is expressed exclusively in the brainstem, with high abundance in the nucleus tractus solitarius. PKR2 mRNA is detected throughout the brain, with prominent expression in olfactory regions, cortex, thalamus and hypothalamus, septum and hippocampus, habenula, amygdala, nucleus tractus solitarius, and circumventricular organs such as subfornical organ, median eminence, and area postrema. PKR2 mRNA is also detected in mammillary nuclei, periaqueductal gray, and dorsal raphe. In contrast, PKR1 mRNA is found in fewer brain regions, with moderate expression in the olfactory regions, dentate gyrus, zona incerta, and dorsal motor vagal nucleus. Both PKR1 and PKR2 are also detected in olfactory ventricle and subventricular zone of the lateral ventricle, both of which are rich sources of neuronal precursors. These extensive expression patterns suggest that prokineticins may have a broad array of functions in the central nervous system, including circadian rhythm, neurogenesis, ingestive behavior, reproduction, and autonomic function.     

Immunocytochemical localization of argininosuccinate synthetase in the rat brain.

The neuronal distribution of argininosuccinate synthetase (ASS) was mapped in the rat brain. Argininosuccinate synthetase is one of the enzymes of the arginine metabolic pathway and catabolizes the synthesis of argininosuccinate from aspartate and citrulline. Since arginine is the precursor of nitric oxide, argininosuccinate synthetase may act as part of the nitric oxide producing pathway. Argininosuccinate is also suggested to have a messenger function in the nervous system. Therefore, the localization of ASS is of great interest. Polyclonal antisera against purified rat liver argininosuccinate synthetase revealed a characteristic distribution pattern of argininosuccinate synthetase-like immunoreactivity: (1) many neurons with strong argininosuccinate synthetase-like immunoreactivity were observed in the septal area, basal forebrain, anterior medial and premammillary nuclei of the hypothalamus, anterior and midline thalamic nuclei, dorsal endopiriform nucleus of the amygdala, basal nucleus of Meynert, subthalamic nucleus, laterodorsal tegmental nucleus, raphe nuclei, nucleus ambiguus, and the area postrema, (2) neuropile staining was dense in the septal areas, hypothalamus, area postrema, nucleus of the solitary tract, and the laminae I and II of the caudal subnucleus of the spinal trigeminal nucleus and the spinal dorsal horn, (3) relay nuclei of the specific sensory systems such as the dorsal lateral geniculate nucleus and the ventral nuclei of the thalamus were devoid of argininosuccinate synthetase-like immunoreactivity, (4) no staining was seen in the large white matter structures such as the internal capsule, corpus callosum, and the anterior commissure, and (5) most of the neurons stained were small or medium in size and appeared to be interneurons. The results suggest that argininosuccinate synthetase affects the widely distributed, neuromodulatory system in the brain.     

Identification of central sites involved in butorphanol-induced feeding in rats

Butorphanol (BT), a mixed kappa- and mu-opioid receptor agonist, induces vigorous food intake in rats. Peripheral injection of BT seems to increase food intake more effectively than intracerebroventricular administration. To further elucidate the nature of BT's influence on consummatory behavior, we examined which feeding-related brain areas exhibit increased c-Fos immunoreactivity (IR) following subcutaneous injection of 4 mg/kg body weight BT, a dose known to induce a maximal orexigenic response. We also evaluated whether direct administration of BT into the forebrain regions activated by peripheral BT injection affects food intake. Peripheral BT administration induced c-Fos-IR in the hypothalamic paraventricular nucleus (PVN), central nucleus of the amygdala (CeA), and nucleus of the solitary tract (NTS). However, 0.1-30 microg BT infused into the CeA, failed to increase food intake 1, 2, and 4 h after injection. Only the highest dose of BT (30 microg) injected into the PVN increased feeding. These results suggest that the PVN, CeA, and NTS mediate the effects of peripherally-injected BT. The PVN or CeA are probably not the main target sites of immediate BT action.     

Immunohistochemical studies of FMRF-amide-like immunoreactivity in rat brain

The anatomical distribution of neuronal perikarya and nerve fibres containing FMRF-amide-like immunoreactivity in the brain, spinal cord and pituitary of the rat has been studied by immunohistochemistry. In animals pretreated with colchicine, the highest concentration of nerve cell bodies occurred in hypothalamic nuclei. Cells were also present in the cortex, striatum, septum, thalamus and in the brainstem. Beaded nerve fibres were abundant in the septum, nucleus of the striae terminalis, hypothalamus, medial regions of the thalamus, the parabrachial nucleus, the ventrolateral medulla, the substantia gelatinosa of the spinal trigeminal nucleus and the dorsal horn of the spinal cord. Fibres were also present in the cortex, striatum, amygdala, pons, ventral spinal cord and the neural lobe of the pituitary. The localization was specific in that preabsorbtion of the antisera with FMRF-amide, but not structurally related molecules such as Met-Enk-Arg6Phe7, APP or BPP, completely abolished the localization. The mammalian counterparts of FMRF-amide may have a neurotransmitter or neuromodulatory role.