A GABA-neuropeptide Y (NPY) interplay in LH release

Neuropeptide Y (NPY) stimulates and gamma-amino butyric acid (GABA) inhibits LH release in the rat. Since a sub-population of NPY-producing neurons in the arcuate nucleus (ARC) of the hypothalamus co-express GABA, the possibility of an interplay between NPY and GABA in the release of LH was investigated in two ways. First by employing light and electron microscopic double staining for NPY and GABA, using pre and post-immunolabeling on rat brain sections, we detected GABA in NPY immunoreactive axon terminals in the MPOA, one of the primary sites of action of these neurotransmitters/neuromodulators in the regulation of LH release. These morphological findings raised the possibility that inhibitory GABA co-released with NPY may act to restrain the excitatory effects of NPY on LH release. Muscimol (MUS, 0.44 or 1.76 nmol/rat), a GABA(A) receptor agonist, administered intracerebroventricularly (icv), alone failed to affect LH release, but NPY (0.47 nmol/rat icv) alone stimulated LH release in ovarian steroid-primed ovariectomized rats. On the other hand, administration of MUS blocked the NPY-induced stimulation of LH release in a dose-dependent manner. Similarly, administration of MUS abolished the excitatory effects on LH release of 1229U91, a selective NPY Y4 receptor agonist. These results support the possibility that in the event of co-release of these neurotransmitters/neuromodulators, GABA may act to restrain stimulation of LH release by NPY during the basal episodic and cyclic release of LH in vivo.

Evidence of NPY Y5 receptor involvement in food intake elicited by orexin A in sated rats

Intracerebroventricular (icv) injections of orexin A stimulate feeding in sated rats. Since neuropeptide Y is a potent orexigenic peptide and orexin-containing neurons are morphologically linked with NPY-producing neurons in the hypothalamus, we evaluated the functional relationship between the two orexigenic peptides. The results show that whereas it was ineffective on its own, a selective NPY Y5 receptor antagonist, injected icv 15 min. before orexin A significantly suppressed orexin A-induced feeding. Since previous investigations demonstrated that an NPY Y1 receptor antagonist also inhibits feeding induced by orexin A, the current results further underscore the existence of a functional link between orexin and NPY producing neurons as the orexin network appears to be capable of influencing NPYergic signaling through Y1 and Y5 receptors to stimulate feeding.

Regulation of leptin secretion: effects of aging on daily patterns of serum leptin and food consumption

We have investigated the effects of age on the daily rise in serum leptin levels during the dark-phase of the light-dark cycle. The results show that in young 7-week-old rats, serum leptin levels increase significantly at 2300 h from the levels at 1500 h in association with increased food consumption. However, in middle-aged rats 25 weeks old, the dark-phase increase in serum leptin is absent despite retention of the daily dark-phase increase in food consumption. When compared to our earlier published results, these finding show that the loss of dark-phase rise in serum leptin occurred despite the daily increase in adipocyte leptin gene expression. These results are in accord with the view that the daily pattern in serum leptin is unlikely to be a contributor to the daily patterning of food consumption.

Melanocortin signaling is decreased during neurotoxin-induced transient hyperphagia and increased body-weight gain

Hypothalamic neuropeptides play critical roles in the regulation of feeding behavior and body weight (BW). Disruption of signaling in the ventromedial nucleus by microinjection of the neurotoxin, colchicine (COL), produces transient hyperphagia with corresponding BW gain lasting for 4 days. Because the melanocortin system exerts an inhibitory control on food intake, we hypothesized that hyperphagia in COL-treated rats is due to decreased melanocortin-induced restraint on feeding. Melanocortin restraint is exerted through alpha-melanocortin-stimulating hormone derived from proopiomelanocortin (POMC) and is antagonized by agouti-related peptide produced in neurons located in the arcuate nucleus (ARC). COL (4 microg/0.5 microl saline) or saline was microinjected bilaterally into the ventromedial nucleus of adult male rats. In conjunction with BW gain, blood leptin levels were elevated, whereas POMC mRNA in the ARC was significantly decreased in COL-injected rats. Levels of alpha-melanocortin-stimulating hormone were also decreased in the micropunched paraventricular nucleus, dorsomedial nucleus, and perifornical hypothalamus, sites implicated in the control of food intake. That diminution in melanocortin signaling underlies hyperphagia was supported by the observation that intracerebroventricular injection of the MC3/MC4 melanocortin receptor agonist, MTII, prevented the hyperphagia and BW gain. Surprisingly, however, mRNA levels of the orexigenic peptide agouti-related peptide in the ARC were decreased perhaps due to the action of elevated leptin. These results show that transient hyperphagia and BW gain induced by disruption of signaling in the ventromedial nucleus results from two neurochemical rearrangements: development of leptin resistance in POMC neurons and diminution in melanocortin signaling as reflected by decreased POMC gene expression in the ARC and decreased availability of alpha-melanocortin-stimulating hormone for release in feeding relevant sites.

A 'palliative' resection which became potentially curative

We report a very unusual case of a woman with rectal cancer, who, at operation, appeared to have peritoneal metastases. An anterior resection was carried out, and subsequent histology showed the rectal tumour to be a well-differentiated Dukes' B adenocarcinoma, which had been completely excised. The apparent 'metastases' were found to be schistosomal granulomas and there was also a schistosomal granuloma within the tumour.

Hypothalamic galanin is up-regulated during hyperphagia and increased body weight gain induced by disruption of signaling in the ventromedial nucleus

Disruption of signaling in the ventromedial nucleus (VMN) by colchicine (COL) produces transient (4 days) hyperphagia and weight gain. Microinjection of galanin into various hypothalamic sites stimulates feeding, so we tested the hypothesis that galanin is up-regulated in COL-treated rats by analyzing galanin concentrations in micropunched hypothalamic sites. Galanin was increased in the paraventricular nucleus on Days 1 through 4 after COL-injection. Galanin was also elevated in three other hypothalamic sites, the dorsomedial nucleus, lateral hypothalamic area, and perifornical hypothalamus, on Days 2-4 and in the lateral preoptic area, on Day 1 only. In the median eminence-arcuate nucleus and amygdala an initial decrease on Day 1 was followed by a then progressive increase through Day 4. These increases occurred despite marked elevations in blood insulin and leptin, hormones known to suppress hypothalamic galanin. When COL- or saline-treated rats were injected intracerebroventricularly with galanin, it stimulated feeding further in the hyperphagic COL-treated rats, but the relative response over basal consumption was similar in both COL-treated and control rats. These results in VMN disrupted rats suggest that neurochemical rearrangements, including increased availability of galanin, may contribute to the hyperphagia and increased weight gain; additionally, it seems that neurons in the VMN normally exert a restraint on galanin signaling.

Effects of centrally administered antisense oligodeoxynucleotides on feeding behavior and hormone secretion

The effects of neurotransmitters and neuromodulators can be interrupted by either blockade or diminution in the amount of release by curtailing the availability of the neuropeptides in the nerve terminals. Theoretically, antisense oligodeoxynucleotides decrease the availability of signals by blocking the transcription process, thus offering an opportunity to dissect the relative roles of neurotransmitters that elicit similar biological responses. Both NPY and GAL stimulate feeding and LHRH secretion, but antisense oligodeoxynucleotides behaved differently in interrupting these two responses. Centrally administered antisense oligodeoxynucleotides were effective in blocking the stimulatory effects of NPY on LH release, thereby demonstrating that neuronal permeability, degradation, and toxicity of oligodeoxynucleotides are not limiting factors. Thus, for short-term studies the unmodified phosphodiester sequences can be successfully used. Because the attempts to block the behavioral effects of NPY yielded equivocal results, it is clear that newly synthesized NPY, critical for LH release, is relatively insignificant for feeding. Blockade of behavioral effects requires a longer period of effectiveness of oligodeoxynucleotides necessitating that the rate of oligodeoxynucleotide degradation be retarded. Effective protection from degradation in vivo can be achieved by phosphorothioating one or two terminal bases. This modification, unlike the earlier practice of phosphorothioate protection of each base, causes no toxicity and is well tolerated after central administration. Adequate controls, including vehicle and similarly modified missense or scrambled sequences, are essential to confirm specificity and to exclude toxicity. The site of administration is another important factor to be considered in the experimental design. Whereas i.c.v. injections (lateral ventricle, or IIIrd ventricle) have been largely effective in allowing access to multiple hypothalamic sites, direct injection into relevant hypothalamic nuclei may provide surgical precision to effect concentrated blockade at the site of synthesis. Earlier studies with centrally administered oligodeoxynucleotides were plagued by these limitations, resulting in inconsistent and equivocal results. However, more recent investigations, designed with these caveats in mind, have successfully used antisense oligodeoxynucleotides as exemplified by the studies to establish the role of the Y5R subtype in transducing the orexigenic NPY signal.

Food intake elicited by central administration of orexins/hypocretins: identification of hypothalamic sites of action

Orexin A and B, a recently identified pair of neuropeptides, are produced in perikarya located in the lateral and perifornical hypothalamus (LH and PFH). Immunoreactive fibers from these neurons innervate several nuclei in the hypothalamus. Orexin A and orexin B stimulate feeding when administered intracerebroventricularly to rats. To identify the specific sites of orexin action, orexin A and B were microinjected into a number of hypothalamic and extrahypothalamic sites in rats. Orexin A was found to enhance food intake when injected into four hypothalamic sites, the paraventricular nucleus (PVN), the dorsomedial nucleus (DMN), LH and the perifornical area, but was ineffective in the arcuate nucleus (ARC), the ventromedial nucleus (VMN), and the preoptic area (POA) as well as the central nucleus of the amygdala (CeA) and nucleus of the tractus solitarius (NTS). Orexin B was not effective at any site tested. These findings demonstrate that orexin A receptive sites for stimulation of food intake exist primarily in a narrow band of neural tissue within the hypothalamus that is known to be involved in control of energy homeostasis.

Comparing the hypothalamic and extrahypothalamic actions of endogenous hyperleptinemia

To determine whether the depletion of body fat caused by adenovirus-induced hyperleptinemia is mediated via the hypothalamus, we used as a "bioassay" for hypothalamic leptin activity the hypothalamic expression of a leptin-regulated peptide, cocaine- and amphetamine-regulated transcript (CART). The validation of this strategy was supported by the demonstration that CART mRNA was profoundly reduced in obese rats with impaired leptin action, whether because of ablation of the ventromedial hypothalamus (VMH) or a loss-of-function mutation in the leptin receptor, as in Zucker diabetic fatty rats. We compared leptin activity in normal rats made hyperleptinemic by adenovirus-leptin treatment (43 +/- 9 ng/ml, cerebrospinal fluid leptin 100 pg/ml) with normal rats made hyperleptinemic by a 60% fat intake (19 +/- 4 ng/ml, cerebrospinal fluid leptin 69 +/- 22 pg/ml). CART was increased 5-fold in the former and 2-fold in the latter, yet in adenovirus-induced hyperleptinemia, body fat had disappeared, whereas in high-fat-fed rats, body fat was abundant. Treatment of the high-fat-fed rats with adenovirus-leptin further increased their hyperleptinemia to 56 +/- 6 ng/ml without changing CART mRNA or food intake, indicating that leptin action on hypothalamus had not been increased. Nevertheless, their body fat declined 36%, suggesting that an extrahypothalamic mechanism was responsible. We conclude that in diet-induced obesity body-fat depletion by leptin requires supraphysiologic plasma concentrations that exceed the leptin-transport capacity across the blood-brain barrier.

Interacting appetite-regulating pathways in the hypothalamic regulation of body weight

Various aspects of the complex spatio-temporal patterning of hypothalamic signaling that leads to the development of synchronized nocturnal feeding in the rat are critically examined. Undoubtedly, as depicted in Fig. 7, a distinct ARN in the hypothalamus is involved in the control of nocturnal appetite. At least four basic elements operate within this ARN. These are: 1) A discrete appetite-driving or orexigenic network of NPY, NE, GABA, GAL, EOP, and orexin transduces and releases appetite-stimulating signals. 2) Similarly, anorexigenic signal-producing pathways (e.g., CRH, GLP-1, alpha MSH, and CART) orchestrate neural events for dissipation of appetite and to terminate feeding, possibly by interrupting NPY efflux and action at a postsynaptic level within the hypothalamus. It is possible that some of these may represent the physiologically relevant "off" switches under the influence of GABA alone, or AgrP alone, or in combination with NPY released from the NPY-, GABA-, and AgrP-coproducing neurons. 3) Recent evidence shows that neural elements in the VMN-DMN complex tonically restrain the orexigenic signals during the intermeal interval; the restraint is greatly aided by leptin's action via diminution of orexigenic (NPY) and augmentation of anorexigenic (GLP-1, alpha MSH, and CART) signals. Since interruption of neurotransmission in the VMN resulted in hyperphagia and development of leptin resistance, it seems likely that the VMN is an effector site for the restraint exercised by leptin. The daily rhythms in leptin synthesis and release are temporally dissociable because the onset of daily rise in leptin gene expression in adipocytes precedes that in leptin secretion. Nevertheless, these rhythms are in phase with daily ingestive behavior because the peak in circulating leptin levels occurs during the middle of the feeding period. These observations, coupled with the fact that circulating levels of leptin are directly related to adiposity, pose a new challenge for elucidating the precise role of leptin in daily patterning of feeding in the rat. 4) A neural timing mechanism also operates upstream from the ARN in the daily management of energy homeostasis. Although the precise anatomical boundaries are not clearly defined, this device is likely to be composed of a group of neurons that integrate incoming internal and external information for the timely onset of the drive to eat. Evidently, this network operates independently in primates, but it is entrained to the circadian time keeper in the SCN of rodents. Apart from its role in the onset of drive to eat, the circadian patterns of gene expression of NPY, GAL, and POMC denote independent control of the timing device on the synthesis and availability for release of orexigenic signals. The VMN-DMN-PVN complex is apparently an integrated constituent of the timing mechanism in this context, because lesions in each of these sites result in loss of regulated feeding. The accumulated evidence points to the PVN and surrounding neural sites within this framework as the primary sites of release and action of various orexigenic and anorexigenic signals. A novel finding is the identification of the interconnected wiring of the DMN-mPVN axis that may mediate leptin restraint on NPY-induced feeding. The chemical phenotypes of leptin and NPY target neurons in this axis remain to be identified. These multiple orexigenic and anorexigenic pathways in the hypothalamic ARN appear to represent redundancy, a characteristic of regulated biological systems to provide a "fail-safe" neural mechanism to meet an organism's constant energy needs for growth and maintenance. Within this formulation, the coexisting orexigenic signals (NPY, NE, GAL, GABA, and AgrP) represent either another level of redundancy or it is possible that these signals operate within the ARN as reinforcing agents to varying degrees under different circumstances. (ABSTRACT TRUNCATED)

Interacting appetite-regulating pathways in the hypothalamic regulation of body weight

Various aspects of the complex spatio-temporal patterning of hypothalamic signaling that leads to the development of synchronized nocturnal feeding in the rat are critically examined. Undoubtedly, as depicted in Fig. 7, a distinct ARN in the hypothalamus is involved in the control of nocturnal appetite. At least four basic elements operate within this ARN. These are: 1) A discrete appetite-driving or orexigenic network of NPY, NE, GABA, GAL, EOP, and orexin transduces and releases appetite-stimulating signals. 2) Similarly, anorexigenic signal-producing pathways (e.g., CRH, GLP-1, alpha MSH, and CART) orchestrate neural events for dissipation of appetite and to terminate feeding, possibly by interrupting NPY efflux and action at a postsynaptic level within the hypothalamus. It is possible that some of these may represent the physiologically relevant "off" switches under the influence of GABA alone, or AgrP alone, or in combination with NPY released from the NPY-, GABA-, and AgrP-coproducing neurons. 3) Recent evidence shows that neural elements in the VMN-DMN complex tonically restrain the orexigenic signals during the intermeal interval; the restraint is greatly aided by leptin's action via diminution of orexigenic (NPY) and augmentation of anorexigenic (GLP-1, alpha MSH, and CART) signals. Since interruption of neurotransmission in the VMN resulted in hyperphagia and development of leptin resistance, it seems likely that the VMN is an effector site for the restraint exercised by leptin. The daily rhythms in leptin synthesis and release are temporally dissociable because the onset of daily rise in leptin gene expression in adipocytes precedes that in leptin secretion. Nevertheless, these rhythms are in phase with daily ingestive behavior because the peak in circulating leptin levels occurs during the middle of the feeding period. These observations, coupled with the fact that circulating levels of leptin are directly related to adiposity, pose a new challenge for elucidating the precise role of leptin in daily patterning of feeding in the rat. 4) A neural timing mechanism also operates upstream from the ARN in the daily management of energy homeostasis. Although the precise anatomical boundaries are not clearly defined, this device is likely to be composed of a group of neurons that integrate incoming internal and external information for the timely onset of the drive to eat. Evidently, this network operates independently in primates, but it is entrained to the circadian time keeper in the SCN of rodents. Apart from its role in the onset of drive to eat, the circadian patterns of gene expression of NPY, GAL, and POMC denote independent control of the timing device on the synthesis and availability for release of orexigenic signals. The VMN-DMN-PVN complex is apparently an integrated constituent of the timing mechanism in this context, because lesions in each of these sites result in loss of regulated feeding. The accumulated evidence points to the PVN and surrounding neural sites within this framework as the primary sites of release and action of various orexigenic and anorexigenic signals. A novel finding is the identification of the interconnected wiring of the DMN-mPVN axis that may mediate leptin restraint on NPY-induced feeding. The chemical phenotypes of leptin and NPY target neurons in this axis remain to be identified. These multiple orexigenic and anorexigenic pathways in the hypothalamic ARN appear to represent redundancy, a characteristic of regulated biological systems to provide a "fail-safe" neural mechanism to meet an organism's constant energy needs for growth and maintenance. Within this formulation, the coexisting orexigenic signals (NPY, NE, GAL, GABA, and AgrP) represent either another level of redundancy or it is possible that these signals operate within the ARN as reinforcing agents to varying degrees under different circumstances. (ABSTRACT TRUNCATED)

Disruption of neural signaling within the hypothalamic ventromedial nucleus upregulates galanin gene expression in association with hyperphagia: an in situ hybridization analysis

Hypothalamic neuropeptides play critical roles in the regulation of appetite and body weight. We recently reported that disruption of neural signaling in the ventromedial nucleus (VMN) by microinjection of the neurotoxin, colchicine (COL), produced transient hyperphagia with attendant body weight gain lasting for 4 days. The neural mechanism(s) underlying this temporary shift in energy homeostasis is still unknown. Galanin (GAL) is produced in several hypothalamic nuclei and since microinjection of GAL into these sites stimulates feeding, we tested the hypothesis that galaninergic signaling is upregulated in COL-treated rats. COL (4 microgram in 0.5 microliter saline) or saline alone was microinjected into the VMN of adult male rats and GAL mRNA was evaluated in the basal hypothalamus by ribonuclease protection assay on day 1, day 2 and day 4 after injection. Whereas in saline-treated rats body weight and GAL mRNA remained unaffected, they were significantly increased in COL-injected rats through the period of observation. To identify the specific neuronal subpopulations involved, GAL mRNA levels were analyzed in feeding-related hypothalamic nuclei using semiquantitative in situ hybridization histochemistry on day 4 after microinjection of COL or saline into the VMN. In COL-treated rats, GAL mRNA levels increased dramatically over controls in the supraoptic nucleus, paraventricular nucleus (PVN), dorsomedial nucleus (DMN), arcuate nucleus (ARC) and lateral hypothalamic area (LHA); no significant change was observed in the central nucleus of amygdala. These results indicated that disruption of neurotransmission in the VMN upregulated GAL gene expression in those hypothalamic sites (PVN, DMN, LHA and ARC) that are implicated in regulation of feeding, and since GAL stimulates feeding, this neurochemical rearrangement may contribute to the over-eating in these animals. These results also suggest that, normally, neurons in the VMN may suppress GAL neurotransmission in feeding-regulating hypothalamic neural circuits.

Disruption in neuropeptide Y and leptin signaling in obese ventromedial hypothalamic-lesioned rats

Electrolytic lesions placed in the ventromedial hypothalamus (VMH) of rats induce instant hyperphagia and excessive weight gain. Since neuropeptide Y (NPY) is a potent hypothalamic orexigenic signal, and leptin secreted by adipocytes regulates NPY output, we tested the hypothesis that altered NPYergic-leptin signaling may underlie hyperphagia in VMH-lesioned rats. VMH-lesioned rats exhibiting hyperphagia and excessive weight gain in a time-related fashion were sacrificed on days 2, 7, and 21 post-surgery. Quite unexpectedly, NPY concentrations in the hypothalamic paraventricular nucleus (PVN), a major site of NPY release for stimulation of feeding, and in other sites, such as the dorsomedial nucleus, lateral hypothalamic area and median eminence-arcuate nucleus decreased, with the earliest diminution occurring on day 2 in the PVN only. In vitro basal and K+-evoked NPY release from the PVN of VMH-lesioned rats was significantly lower than that of controls. Analysis of hypothalamic NPY gene expression showed that although the daily decrease in NPY mRNA from 0800 to 2200 h occurred as in control rats, NPY mRNA concentrations were markedly reduced at these times in the hypothalami of VMH-lesioned rats. Leptin synthesis in adipocytes as indicated by leptin mRNA levels was also profoundly altered in VMH-lesioned rats. The daily pattern of increase in adipocyte leptin mRNA at 2200 h from 0800 h seen in controls was abolished, higher levels of leptin gene expression at 2200 h were maintained at 0800 h. The pattern of increase in serum leptin and insulin levels diverged in VMH-lesioned rats. Serum insulin concentration increased to maximal on day 2 and remained at that level on day 21-post-lesion; serum leptin levels on the other hand, increased slowly in a time-related fashion during this period. These results demonstrate that hyperphagia and excessive weight gain in VMH-lesioned rats are associated with an overall decrease in hypothalamic NPY and augmented leptin signaling to the hypothalamus. The divergent time course of increases in serum leptin and insulin levels suggest independent mechanisms responsible for their augmented secretion, and neither these hormones nor VMH lesions altered the daily rhythm in NPY gene expression. These observations underscore the existence of an independent mechanism controlling the daily rhythm in hypothalamic NPY gene expression and suggest that leptin feedback action requires an intact VMH.

Neuropeptide Y release in the paraventricular nucleus is decreased during transient hyperphagia induced by microinjection of colchicine into the ventromedial nucleus of rats

Disruption of neural signaling in the ventromedial nucleus (VMN) of rats by microinjection of the neurotoxin colchicine (COL) results in transient hyperphagia accompanied by enhanced weight gain. We tested the hypothesis that release of neuropeptide Y (NPY), a potent orexigenic signal is augmented within the paraventricular nucleus (PVN) of COL-treated hyperphagic rats. Adult male rats were microinjected bilaterally with either COL (4 microg/0.5 microl in saline) or saline in the VMN and a push-pull guide cannula aimed at the PVN was implanted for analysis of extra-cellular NPY. COL-injected rats gained 37.8+/-6.1 g while the saline-injected rats lost 9.3+/-3.4 g during the 4 days following surgery. On day 4, post-injection, the PVN of these rats was perfused with artificial cerebrospinal fluid via the push-pull cannula. NPY levels in perfusates collected at 10 min intervals from hyperphagic, COL-injected rats were markedly diminished. Cumulative NPY efflux over the 180 min sampling period was significantly less in COL-treated (27.7+/-6.0 pg) versus saline-injected control rats (110.6+/-32.2 pg; P < 0.05). These results show that impairment of neural signaling in the VMN by COL suppressed NPY release in the PVN. These observations taken together with previous studies showing diminution in preproNPY mRNA in the arcuate nucleus (ARC) and NPY levels in the PVN are in accordance with the thesis that the VMN normally exerts a facilitatory influence on NPYergic signaling in the ARC-PVN axis.

Resistance to adenovirally induced hyperleptinemia in rats. Comparison of ventromedial hypothalamic lesions and mutated leptin receptors

Leptin regulates appetite and body weight via hypothalamic targets, but it can act directly on cultured pancreatic islets to regulate their fat metabolism. To obtain in vivo evidence that leptin may act peripherally as well as centrally, we compared the effect of adenovirally induced hyperleptinemia on food intake, body weight, and islet fat content in ventromedial hypothalamic-lesioned (VMHL) rats, sham-lesioned (SL) controls, and Zucker Diabetic Fatty (ZDF) rats in which the leptin receptor is mutated. Infusion with recombinant adenovirus containing the rat leptin cDNA increased plasma leptin by approximately 20 ng/ml in VMHL and ZDF rats but had no effect on their food intake, body weight, or fat tissue weight. Caloric matching of hyperphagic VMHL rats to SL controls did not reduce their resistance to hyperleptinemia. Whereas prediabetic ZDF rats had a fourfold elevation in islet fat, in VMHL rats islet fat was normal and none of them became diabetic. Isolated islets from ZDF rats were completely resistant to the lipopenic action of leptin, while VMHL islets exhibited 50% of the normal response; caloric matching of VMHL rats to SL controls increased leptin responsiveness of their islets to 92% of controls. We conclude that leptin regulation of adipocyte fat requires an intact VMH but that islet fat content is regulated independently of the VMH.

Evidence that dark-phase hyperphagia induced by neurotoxin 6-hydroxydopamine may be due to decreased leptin and increased neuropeptide Y signaling

Hyperphagia and obesity can be experimentally induced in rodents by microinjection of 6-hydroxydopamine (6-OHDA) into the ventral noradrenergic bundle (VNAB) to interrupt efferent catecholaminergic pathways to the hypothalamus. Since hypothalamic neuropeptide Y (NPY) is implicated in the control of ingestive behavior, we evaluated hypothalamic NPY activity in this model of obesity. Adult male rats injected bilaterally with 12 microg of 6-OHDA in the VNAB displayed an enhanced rate of body weight gain and selective dark-phase hyperphagia that started at about 10 days postinjection and persisted for the entire duration of the experiment. NPY gene expression, assessed by ribonuclease protection assay, was significantly higher in the hypothalami of 6-OHDA-treated hyperphagic rats during the dark phase (p < 0.01 vs. levels during the light phase and in control, vehicle-injected rats). We also evaluated gene expression of NPY Y and Y5 receptors, receptor subtypes reported to mediate NPY-induced feeding. The dark-phase increase in NPY mRNA was accompanied by the concomitant upregulation of NPY Y5R gene expression, but not of Y1R mRNA levels. Leptin, the peripheral hormone secreted by adipocytes, is believed to maintain body weight and inhibit food intake, most likely by suppressing hypothalamic NPY activity. Evaluation of leptin gene expression in the epididymal fat revealed that the upregulation of leptin mRNA noted during the dark phase in control rats did not occur in 6-OHDA-treated rats. These observations implied that the normal restraint on NPY and feeding exercised by leptin in control rats may be abrogated in 6-OHDA-treated hyperphagic rats due to insufficient levels of leptin. If so, administration of leptin should inhibit food intake in these rats. Indeed, injection of leptin (2 mg/kg, intraperitoneally (i.p.)) on 2 consecutive days reduced 24-h food intake by 25% and significantly reduced body weight. These results suggest that the nocturnal hyperphagia and resultant obesity induced by 6-OHDA injected into the VNAB may be attributed to leptin deficiency concomitant with increased hypothalamic NPY.

Anorectic effects of the cytokine, ciliary neurotropic factor, are mediated by hypothalamic neuropeptide Y: comparison with leptin

Although ciliary neurotropic factor (CNTF) is a tropic factor in nervous system development and maintenance, peripheral administration of this cytokine also causes severe anorexia and weight loss. The neural mechanism(s) mediating the loss of appetite is not known. As hypothalamic neuropeptide Y (NPY) is a potent orexigenic signal, we tested the hypothesis that CNTF may adversely affect NPYergic signaling in the hypothalamus. Intraperitoneal administration of CNTF (250 microg/kg) daily for 4 days significantly suppressed 24-h food intake in a time-dependent manner and decreased body weight. The loss in body weight was similar to that which occurred in pair-fed (PF) rats. As expected, hypothalamic NPY gene expression, determined by measurement of steady state prepro-NPY messenger RNA by ribonuclease protection assay, significantly increased in PF rats in response to energy imbalance. However, despite a similar loss in body weight, there was no increase in NPY gene expression in CNTF-treated rats. Daily administration of CNTF intracerebroventricularly (0.5 or 5.0 microg/rat) also produced anorexia and body weight loss. In this experiment, negative energy balance produced by both PF and food deprivation augmented hypothalamic NPY gene expression. However, despite reduced intake and loss of body weight, no similar increment in hypothalamic NPY gene expression was observed in CNTF-treated rats. In fact, in rats treated with higher doses of CNTF (5.0 microg/rat), NPY gene expression was reduced below the levels seen in control, freely fed rats. Furthermore, CNTF treatment also markedly decreased NPY-induced feeding. These results suggested that anorexia in CNTF-treated rats may be due to a deficit in NPY supply and possibly in the release and suppression of NPY-induced feeding. The possibility that CNTF-induced anorexia may be caused by increased leptin was next examined. Daily intracerebroventricular injections of leptin (7 microg/rat) decreased food intake, body weight, and hypothalamic NPY gene expression in a manner similar to that seen after CNTF treatment. Leptin administration also suppressed NPY-induced feeding. However, peripheral and central CNTF injections markedly decreased leptin messenger RNA in lipocytes, indicating a deficiency of leptin in these rats; thus, leptin was unlikely to be involved in appetite suppression. Thus, these results show that a two-pronged central action of CNTF, causing diminution in both NPY availability and the NPY-induced feeding response, may underlie the severe anorexia. Further, unlike other members of the cytokine family, suppression of NPYergic signaling in the hypothalamus by CNTF does not involve up-regulation of leptin, but may involve a direct action on hypothalamic NPY neurons or on neural circuits that regulate NPY signaling in the hypothalamus.

Leptin and ciliary neurotropic factor (CNTF) inhibit fasting-induced suppression of luteinizing hormone release in rats: role of neuropeptide Y

Periods of chronic undernutrition and short periods of fasting suppress pituitary luteinizing hormone (LH) secretion and upregulate hypothalamic neuropeptide Y (NPY), the orexigenic peptide. The effect of suppression of NPY upregulation with ciliary neurotropic factor (CNTF), a cytokine, and leptin, an adipocyte hormone, on pituitary LH secretion was evaluated in fasted rats. In the first experiment, daily injection of CNTF (0.2 nmol) intracerebroventricularly (i.c.v.) for 4 days drastically reduced food intake and body weight gain similar to the weight loss seen in pair-fed rats. Food deprivation (FD) also decreased body weight. Despite drastic loss in body weight, plasma LH was reduced in FD and pair-fed rats, but not in CNTF-treated rats. In the second experiment, FD rats received either control vehicle, CNTF (0.2 nmol) or leptin (0.2 nmol) daily for 4 days. FD increased steady state levels of preproNPY mRNA in the hypothalamus over the control freely-fed rats. However, both CNTF and leptin suppressed hypothalamic gene expression and significantly attenuated LH suppression in response to FD. Taken together, these results support the hypothesis that the upregulation of hypothalamic NPY system may underlie diminution in pituitary gonadotropin secretion and that the NPYergic pathway may serve as a communication bridge between the neural processes that regulate reproduction and those that maintain energy balance.

Neuropeptide Y (NPY) Y1 receptor mRNA is upregulated in association with transient hyperphagia and body weight gain: evidence for a hypothalamic site for concurrent development of leptin resistance

Microinjection of colchicine (COL), a neurotoxin that blocks axoplasmic flow in the neurons, bilaterally into the ventromedial nucleus (VMN) evokes transient hyperphagia and body weight gain. These shifts in energy balance occurred in conjunction with development of increased sensitivity to neuropeptide Y (NPY), the endogenous orexigenic signal. In order to trace the aetiology of NPY supersensitivity, we have evaluated (1) NPY Y1 and Y5 receptor (R) gene expression in the hypothalamus and (2) the possibility of alterations in the inhibitory action of leptin, a hormone produced by lipocytes. Adult male rats were rendered hyperphagic with bilateral microinjections of COL (4 microg/side) into the VMN. We observed that hypothalamic NPY Y1 mRNA levels, as measured by RNAase protection assay, were significantly increased on day 2 and returned to the control level on day 4 in COL-injected rats. The effects on NPY Y5R mRNA were not as clear cut. Interestingly, serum leptin levels increased in association with the hyperphagia and body weight gain, thereby raising the likelihood of development of resistance to the suppressive effect of endogenous leptin on food intake. Indeed, intracerebroventricular injection of 7 microg human recombinant leptin, a dose that attenuated daily food intake in normal and fasted rats, was completely ineffective in attenuating hyperphagia in COL-treated rats. These results show that transient hyperphagia induced by interruption of signalling in the VMN may be caused by increased sensitivity to NPY, which may be caused, in part, by increased expression of NPY Y1R in hypothalamic sites involved in regulation of ingestive behaviour. Additionally, the observation of increased leptin release and concurrent development of leptin resistance suggest that a normally functioning VMN may be necessary for the central inhibitory effects of leptin on food intake.

Increased receptor sensitivity to neuropeptide Y in the hypothalamus may underlie transient hyperphagia and body weight gain

Disruption of neural signaling by microinjection of a neurotoxin, colchicine (COL), in the ventromedial hypothalamus (VMH) of rats results in rapid and transient hyperphagia and body weight gain. Since neuropeptide Y (NPY) is a potent hypothalamic orexigenic signal and continuous NPY receptor activation by intracerebroventricular (icv) NPY infusion results in hyperphagia and obesity, we tested the hypothesis that altered NPYergic signaling may underlie the transient hyperphagia in COL-injected rats. Immediately following COL (4 microg) microinjections in the ventromedial nucleus (VMN) rats displayed hyperphagia both during the lights-on and lights-off periods. Concomitant with hyperphagia, preproNPY mRNA levels in the arcuate nucleus and NPY levels in the paraventricular nucleus decreased in a time-dependent manner. However, food intake in response to intracerebroventricular injections of NPY (29, 117 and 470 pmole) was significantly higher in COL-injected rats and the latency to initiation of feeding was markedly reduced as compared to controls. The smallest dose of NPY which was virtually ineffective in control rats, evoked near maximal intake in COL-injected rats. This enhanced response lasted for only 4 days paralleling the transient hyperphagia. The NPY Y1 receptor antagonist 1229U91 (5 or 30 microg/rat, icv) significantly suppressed feeding in COL-treated rats thereby indicating that hyperphagia in these rats was dependent upon endogenous NPY. Overall, these studies demonstrate that not only high levels, but low levels of NPY may also result in hyperphagia and increased body weight and this hyperphagia may be attributed to the rapid development of NPY Y1 receptor hypersensitivity.

Insulin and insulin-like growth factor II suppress neuropeptide Y release from the nerve terminals in the paraventricular nucleus: a putative hypothalamic site for energy homeostasis

It has been recently recognized that a distinct signaling pathway in the hypothalamus is involved in the stimulation of feeding in mammals. Neuropeptide Y (NPY), a member of the pancreatic polypeptide family, is the most potent orexigenic signal, and its secretion in discrete hypothalamic sites increases in response to insulinopenia produced by food deprivation or experimental diabetes. To establish the site of interaction between the hypothalamus and the pancreas, we examined the effects of insulin on NPY release in vivo and in vitro from hypothalamic sites known to be involved in feeding behavior. In the first study we evaluated the effects of peripheral insulin injections (1 U/kg.day, sc) on NPY levels in seven hypothalamic nuclei in food-deprived (FD) and ad libitum-fed rats. Whereas food deprivation for 3 days increased NPY levels in the medial preoptic area, paraventricular nucleus (PVN), and arcuate nucleus, insulin injections, which did not alter blood glucose levels, returned NPY levels to the control range selectively in the PVN. NPY levels in the hypothalamic nuclei remained unchanged after insulin injections in ad libitum-fed rats. The in vivo NPY release in the PVN of FD rats, evaluated by the push-pull cannula technique, also decreased in response to peripheral insulin injections. Finally, the effects of insulin, insulin-like growth factor I (IGF-I), and IGF-II on NPY release in vitro from the microdissected PVN and two central neighboring sites, the ventromedial nucleus and the median eminence-arcuate nucleus, of FD rats were evaluated. Both insulin (0.67 or 6.7 nM) and IGF-II (0.7 or 7.0 nM) decreased the release of NPY in a dose-dependent manner only from the PVN. On the other hand, IGF-I (0.07 or 7.0 nM) failed to alter the basal PVN NPY efflux. As the PVN is richly innervated by NPY-containing nerve terminals, the results of these in vivo and in vitro studies suggest that the site of insulin action on the hypothalamic NPY network may reside at the level of PVN nerve terminals or at the interneurons in contact with NPY nerve terminals. Although insulin may have a direct effect in reducing NPY release from the PVN, the effectiveness of IGF-II in decreasing NPY release from the PVN raises the possibility that insulin's action may also be mediated via hypothalamic IGF-II neuronal pathways.

Evidence of a physiological role for neuropeptide Y in ventromedial hypothalamic lesion-induced hyperphagia

We evaluated the role of neuropeptide Y (NPY), a potent endogenous orexigenic signal, in the ventromedial hypothalamic (VMH) lesion-induced hyperphagia in rats. To produce hyperphagia and excessive weight gain, adult female rats received bilateral electrolytic or sham lesions in the VMH. Concurrently, a permanent intracerebroventricular cannula was implanted in the third ventricle of the brain. After a recovery period, these rats were passively immunized against NPY to evaluate the role of endogenous NPY on hyperphagia. The results showed that intraventricular administration of NPY antibodies abolished the hyperphagia in VMH-lesioned rats. These revelations are in agreement with the notion that altered hypothalamic NPY release or action may underlie the hyperphagia and excessive weight gain seen in response to structural damage in the VMH.

The effects of interleukin 1 beta on the hypothalamic tachykinin, neurokinin A

Interleukin-1 beta (IL-1 beta) is a pleiotropic cytokine that appears to be an integral component of the bidirectional signalling between the immune and central nervous systems. It is produced in the hypothalamus and has been shown to inhibit the hypothalamo-pituitary-gonadal axis and to activate the hypothalamo-pituitary-adrenal axis. IL-1 beta is reported to up-regulate the tachykinin, substance P (SP), in the peripheral nervous system. We have recently observed that members of the hypothalamic tachykinin family including SP, neurokinin A (NKA) and two N-terminal extended forms of NKA (neuropeptides kappa and gamma), inhibit hypothalamic LHRH and pituitary LH release and stimulate adrenal corticosterone secretion. The similarity in the endocrine effects of the tachykinins and the cytokine prompted us to test the hypothesis that IL-1 beta may stimulate the hypothalamic tachykinins, which would then mediate the neuroendocrine effects of IL-1 beta. First, the effects of IL-1 beta on the in vitro release of NKA-like immunoreactivity (NKA-li) from the hypothalamus was examined. Addition of 10 nM IL-1 beta significantly increased NKA-li release from the hypothalami of castrated rats, but not from the hypothalami of intact rats. To identify the site of IL-1 beta action, the effects of intraventricular IL-1 beta (100 ng) on NKA-li levels in various hypothalamic sites of intact and castrated rats were examined. The results showed that IL-1 beta increased NKA-li selectively in the median eminence (ME) and arcuate nucleus (ARC) of castrated rats only.(ABSTRACT TRUNCATED AT 250 WORDS)

Naloxone reduces the feeding evoked by intracerebroventricular galanin injection

Central injection of galanin elicits feeding in satiated rats. We recently observed galanin-immunoreactive fibers in synaptic connection with a population of beta-endorphin-immunopositive cell bodies and dendrites in the basal hypothalamus. Because beta-endorphin also stimulates food intake, these morphological findings raised the possibility that stimulation of feeding by galanin may, in part, be mediated by beta-endorphin release. First, we observed that ICV injection of galanin (1.5-6.0 nmol) stimulated feeding in a dose-related fashion. Next, the effect on food intake of the opioid receptor antagonist naloxone (20-200 micrograms, ICV) administered immediately preceding galanin (3 nmol, ICV) was evaluated. Galanin-induced feeding was suppressed by naloxone in a dose-dependent manner with a maximal suppression of 76% at the highest naloxone dose. These findings support the existence of a functional link between galanin and beta-endorphin and are in accord with the view that stimulation of food intake by galanin may, in part, be mediated by increased beta-endorphin release.