Roux-en-Y Gastric Bypass and Caloric Restriction but Not Gut Hormone-Based Treatments Profoundly Impact the Hypothalamic Transcriptome in Obese Rats.

BACKGROUND: The hypothalamus is an important brain region for the regulation of energy balance. Roux-en-Y gastric bypass (RYGB) surgery and gut hormone-based treatments are known to reduce body weight, but their effects on hypothalamic gene expression and signaling pathways are poorly studied. METHODS: Diet-induced obese male Wistar rats were randomized into the following groups: RYGB, sham operation, sham + body weight-matched (BWM) to the RYGB group, osmotic minipump delivering PYY3-36 (0.1 mg/kg/day), liraglutide s.c. (0.4 mg/kg/day), PYY3-36 + liraglutide, and saline. All groups (except BWM) were kept on a free choice of high- and low-fat diets. Four weeks after interventions, hypothalami were collected for RNA sequencing. RESULTS: While rats in the RYGB, BWM, and PYY3-36 + liraglutide groups had comparable reductions in body weight, only RYGB and BWM treatment had a major impact on hypothalamic gene expression. In these groups, hypothalamic leptin receptor expression as well as the JAK-STAT, PI3K-Akt, and AMPK signaling pathways were upregulated. No significant changes could be detected in PYY3-36 + liraglutide-, liraglutide-, and PYY-treated groups. CONCLUSIONS: Despite causing similar body weight changes compared to RYGB and BWM, PYY3-36 + liraglutide treatment does not impact hypothalamic gene expression. Whether this striking difference is favorable or unfavorable to metabolic health in the long term requires further investigation.

Prokineticin 2 facilitates mechanical allodynia induced by α,ß-methylene ATP in rats.

Prokineticin 2 (PK2), a new chemokine, causes mechanical hypersensitivity in the rat hind paw, but little is known about the molecular mechanism. Here, we have found that ionotropic P2X receptor is essential to mechanical allodynia induced by PK2. First, intraplantar injection of high dose (3 or 10 pmol) of PK2 significantly increased paw withdrawal response frequency (%) to innocuous mechanical stimuli (mechanical allodynia). And the mechanical allodynia induced by PK2 was prevented by co-administration of TNP-ATP, a selective P2X receptor antagonist. Second, although low dose (0.3 or 1 pmol) of PK2 itself did not produce an allodynic response, it significantly facilitated the mechanical allodynia evoked by intraplantar injection of α,ß-methylene ATP (α,ß-meATP). Third, PK2 concentration-dependently potentiated α,ß-meATP-activated currents in rat dorsal root ganglion (DRG) neurons. Finally, PK2 receptors and intracellular signal transduction were involved in PK2 potentiation of α,ß-meATP-induced mechanical allodynia and α,ß-meATP-activated currents, since the potentiation were blocked by PK2 receptor antagonist PKRA and selective PKC inhibitor GF 109203X. These results suggested that PK2 facilitated mechanical allodynia induced by α,ß-meATP through a mechanism involved in sensitization of cutaneous P2X receptors expressed by nociceptive nerve endings.

Stable oxyntomodulin analogues exert positive effects on hippocampal neurogenesis and gene expression as well as improving glucose homeostasis in high fat fed mice.

The weight-lowering and gluco-regulatory actions of oxyntomodulin (Oxm) have been well-documented however potential actions of this peptide in brain regions associated with learning and memory have not yet been evaluated. The present study examined the long-term actions of a stable acylated analogue of Oxm, (dS(2))Oxm(K-γ-glu-Pal), together with parent (dS(2))Oxm peptide, on hippocampal neurogenesis, gene expression and metabolic control in high fat (HF) mice. Groups of HF mice (n = 12) received twice-daily injections of Oxm analogues (both at 25 nmol/kg body weight) or saline vehicle (0.9% wt/vol) over 28 days. Hippocampal gene expression and histology were assessed together with evaluation of energy intake, body weight, non-fasting glucose and insulin, glucose tolerance, insulin sensitivity and lipids. Oxm analogues significantly reduced body weight, improved glucose tolerance, glucose-mediated insulin secretion, insulin sensitivity, islet architecture and lipid profile. Analysis of brain histology revealed significant reduction in hippocampal oxidative damage (8-oxoguanine), enhanced hippocampal neurogenesis (doublecortin) and improved hippocampal and cortical synaptogenesis (synaptophysin) following treatment. Furthermore, Oxm analogues up-regulated hippocampal mRNA expression of MASH1, Synaptophysin, SIRT1, GLUT4 and IRS1, and down-regulated expression of LDL-R and GSK3ß. These data demonstrate potential of stable Oxm analogues, and particularly (dS(2))Oxm(K-γ-glu-Pal) to improve metabolic function and enhance neurogenesis, synaptic plasticity, insulin signalling and exert protective effects against oxidative damage in hippocampus and cortex brain regions in HF mice.

Evaluation of the degradation and metabolic effects of the gut peptide xenin on insulin secretion, glycaemic control and satiety.

Recently, glucagon-like peptide 1 (GLP1) and glucose-dependent insulinotropic polypeptide (GIP) have received much attention regarding possible roles in aetiology and treatment of type 2 diabetes. However, peptides co-secreted from the same enteroendocrine cells are less well studied. The present investigation was designed to characterise the in vitro and in vivo effects of xenin, a peptide co-secreted with GIP from intestinal K-cells. We examined the enzymatic stability, insulin-releasing activity and associated cAMP production capability of xenin in vitro. In addition, the effects of xenin on satiety, glucose homoeostasis and insulin secretion were examined in vivo. Xenin was time dependently degraded (t(1/2)=162±6 min) in plasma in vitro. In clonal BRIN-BD11 cells, xenin stimulated insulin secretion at 5.6 mM (P<0.05) and 16.7 mM (P<0.05 to P<0.001) glucose levels compared to respective controls. Xenin also exerted an additive effect on GIP, GLP1 and neurotensin-mediated insulin secretion. In clonal ß-cells, xenin did not stimulate cellular cAMP production, alter membrane potential or elevate intra-cellular Ca(2)(+). In normal mice, xenin exhibited a short-acting (P<0.01) satiety effect at high dosage (500 nmol/kg). In overnight fasted mice, acute injection of xenin enhanced glucose-lowering and elevated insulin secretion when injected concomitantly or 30 min before glucose. These effects were not observed when xenin was administered 60 min before the glucose challenge, reflecting the short half-life of the native peptide in vivo. Overall, these data demonstrate that xenin may have significant metabolic effects on glucose control, which merit further study.

Prokineticin 2 is a hypothalamic neuropeptide that potently inhibits food intake.

OBJECTIVE: Prokineticin 2 (PK2) is a hypothalamic neuropeptide expressed in central nervous system areas known to be involved in food intake. We therefore hypothesized that PK2 plays a role in energy homeostasis. RESEARCH DESIGN AND METHODS: We investigated the effect of nutritional status on hypothalamic PK2 expression and effects of PK2 on the regulation of food intake by intracerebroventricular (ICV) injection of PK2 and anti-PK2 antibody. Subsequently, we investigated the potential mechanism of action by determining sites of neuronal activation after ICV injection of PK2, the hypothalamic site of action of PK2, and interaction between PK2 and other hypothalamic neuropeptides regulating energy homeostasis. To investigate PK2's potential as a therapeutic target, we investigated the effect of chronic administration in lean and obese mice. RESULTS: Hypothalamic PK2 expression was reduced by fasting. ICV administration of PK2 to rats potently inhibited food intake, whereas anti-PK2 antibody increased food intake, suggesting that PK2 is an anorectic neuropeptide. ICV administration of PK2 increased c-fos expression in proopiomelanocortin neurons of the arcuate nucleus (ARC) of the hypothalamus. In keeping with this, PK2 administration into the ARC reduced food intake and PK2 increased the release of alpha-melanocyte-stimulating hormone (alpha-MSH) from ex vivo hypothalamic explants. In addition, ICV coadministration of the alpha-MSH antagonist agouti-related peptide blocked the anorexigenic effects of PK2. Chronic peripheral administration of PK2 reduced food and body weight in lean and obese mice. CONCLUSIONS: This is the first report showing that PK2 has a role in appetite regulation and its anorectic effect is mediated partly via the melanocortin system.

Identification of two prokineticin cDNAs: recombinant proteins potently contract gastrointestinal smooth muscle.

The motility of gastrointestinal tract is regulated by classical neurotransmitters, neuropeptides, and humoral agents. Two novel human cDNAs have been cloned based on their sequence similarity to a frog skin secretion protein, Bv8, and a nontoxic protein of mamba snake venom. These human cDNAs encode two secreted proteins of 86 and 81 amino acids. Northern blot hybridization has revealed that these cDNAs are expressed in gastrointestinal tract, particularly the stomach. Recombinant proteins with authentic N-terminal sequences have been produced in Escherichia coli and refolded into functional proteins by careful control of protein aggregation. Mass spectrometry has confirmed the formation of five pairs of disulfide bonds. The refolded recombinant proteins potently contract gastrointestinal smooth muscle with EC(50) values in the subnanomolar range. The contractile effects of the recombinant proteins are specific for gastrointestinal smooth muscle, because they have no effect on vascular or respiratory smooth muscle. To reflect their potent and specific effects on gastrointestinal smooth muscle cells, we have named these recombinant proteins prokineticins. Ligand binding studies with iodinated prokineticin revealed the presence of a high-affinity site in ileal smooth muscle. The displacement of specific binding by GTP gamma S suggests that the prokineticin receptor may belong to the family of G protein-coupled receptors. Experiments with verapamil and nifedipine revealed that calcium influx is essential for the contractile activity of prokineticins on gastrointestinal smooth muscle. In summary, we have identified two novel endogenous regulators of gastrointestinal motility. The availability of recombinant prokineticins should provide novel therapeutic agents for disorders involving impaired gastrointestinal motility.

Xenin--a novel suppressor of food intake in rats.

Peptides related to the amphibian octapeptide xenopsin are present in various locations in mammalians, such as the gastrointestinal mucosa or brain tissue. In the gastrointestinal tract, xenopsin-related peptides induce partially neurogenic contractions of the colon in humans. In brain, however, their function is not known. Structural similarities of xenopsin-related peptides with neurotensin, a known modulator of ingestive behavior, suggest a possible role in feeding regulation. Therefore, we examined the effect of xenin, a recently identified xenopsin-related pentacosa peptide, on feeding behavior of fasted rats. Male Wistar rats (n=12) were intracerebroventricularly (i.c.v.) injected with either saline (10 microl) or xenin at 0.5, 1.5, 5 or 15 microg dissolved in an identical volume of 10 microl, respectively. In further experiments, xenin 15 microg/0.5 microl or 0.5 microl saline were injected into the lateral hypothalamus (LH). After injections, food intake (g), percentage of time spent with feeding (%) and prandial water intake (ml) were subsequently recorded for 2 h. After i.c.v. injection of 15 microg of xenin 1-h food intake was significantly reduced by 42% and 2-h food intake was diminished by 25%, respectively, compared to saline injection (p<0.01). This reduction of food intake was paralleled by a significant decrease of time spent with feeding by 41% (after 1 h) or 23% (after 2 h). The xenin-induced suppression of feeding behavior was dose-dependent. Thus, the minimal effective dose of xenin was 1.5 microg, while the dose of 0.5 microg was ineffective. Prandial water intake was significantly reduced only by the highest dose of xenin. Following injection of 15 microg of xenin into the lateral hypothalamus food intake was not different from control experiments. These data demonstrate a potent feeding suppressive action of xenin following intracerebroventricularly injection but not injection into the lateral hypothalamus suggesting a possible role of xenin in the central control of feeding termination and satiety.

Characterization of neuropeptide Y receptor subtypes in the normal human brain, including the hypothalamus.

The aim of the present study was to investigate the existence and distribution of neuropeptide Y receptor subtypes in various regions of the normal human brain using the peptide YY derivative receptor probes, [125I][Leu31,Pro34]polypeptide YY/Y1 and [125I]polypeptide YY(3-36)/Y2, in addition to the non-selective ligand [125I]polypeptide YY. Membrane binding assays performed with post mortem frontal cortex homogenates revealed that [125I]polypeptide YY and [125I]polypeptide YY(3-36) bound in a time- and protein concentration-dependent manner. Very low amounts of specific [125I][Leu31,Pro34]polypeptide YY binding could be detected even in the presence of high amounts of protein, contrasting with results obtained with [125I]polypeptide YY and [125I]polypeptide YY(3-36), a preferential Y2 receptor probe. Analysis of saturation isotherms revealed that [125I]polypeptide YY(3-36) bound to a single class of high-affinity sites (0.5-2 nM). Significantly higher binding capacities were evident for [125I]polypeptide YY(3-36) as compared to [125I][Leu31,Pro34]polypeptide YY, suggesting that the human frontal cortex, in contrast to the rat, is mostly enriched with Y2 receptors. Ligand selectivity profile confirmed the hypothesis that polypeptide YY(3-36), neuropeptide Y and polypeptide YY but not the [Leu31,Pro34] derivatives are potent competitors of [125I]polypeptide YY and [125I]polypeptide YY(3-36) binding sites. Autoradiographic studies demonstrated further that cortical areas, as well as most other regions of the human brain, are particularly enriched with Y2/[125I]polypeptide YY(3-36) sites, while only low to very low amounts of Y1 binding were detected except in the dentate gyrus of the hippocampal formation. In the human hypothalamus, a preponderance of Y2 binding sites was also noted. Taken together, these results clearly establish that the distribution of the Y1 and Y2 receptor subtypes in human is different from the rodent brain, the Y2 subtype being most abundant in the human brain.

Adjuvant hormonal treatment with peptide YY or its analog decreases human pancreatic carcinoma growth.

BACKGROUND: Recent studies have revealed decreased pancreatic cancer cell growth upon administration of peptide YY (PYY). We examined whether adjuvant treatment with PYY or its synthetic analog, BIM-43004, would decrease human pancreatic adenocarcinoma growth. MATERIALS AND METHODS: Human pancreatic ductal adenocarcinomas, MiaPaCa-2 and BxPC-3, were cultured and assessed for growth by MTT assay. Pancreatic cancer cells received 500 pmol of PYY or BIM-43004 for 24 hours prior to 5-fluorouracil (5-FU; 10 micrograms/mL) and leucovorin (40 micrograms/mL) administration. Cell membrane epidermal growth factor (EGF) receptors were analyzed by Western blotting after exposure to peptides and chemotherapy. RESULTS: Cancer cell growth was reduced in all groups receiving hormonal pretreatment (23% PYY/5-FU/leucovorin versus control; 27% BIM-43004/5-FU/leucovorin versus control) as compared with groups receiving 5-FU and leucovorin only (16% versus control). The EGF receptor expression was reduced by 30% in cells treated with PYY/5-FU/leucovorin and by 45% in cells treated with BIM/5-FU/leucovorin as compared with control cells without treatment. CONCLUSION: Human pancreatic cancer cell growth is further decreased when pretreated with PYY or its synthetic analog prior to chemotherapy.

Peripheral peptide YY induces c-fos-like immunoreactivity in the rat brain.

The influence of peripheral injection of peptide YY (PYY) on neuronal activity in the rat brain was examined by immunohistochemical detection of c-fos protein. Numerous c-fos-immunoreactive nuclei were found in the area postrema, nucleus tractus solitarius (commissural and medial subnuclei), central amygdala and thalamus (periventricular and medial) of rats injected i.p. with PYY at a dose of 300 micrograms/kg. c-fos-like immunoreactivity was found to be less when lower doses of PYY (50-200 micrograms/kg, i.p.) were injected. Either no or few cells were detected after i.p. injection of the vehicle alone. These data provide anatomical support for the centrally mediated actions of peripheral PYY on gut function.

Central stimulation of oxytocin release in the lactating rat: interaction of neuropeptide Y with alpha-1-adrenergic mechanisms.

The possible cooperation of neuropeptide Y (NPY) and alpha-1-adrenergic mechanisms in the release of oxytocin (OT) in conscious, nonsuckled lactating rats was examined following microinjections of NPY and its analogs and/or alpha-adrenergic drugs into the supraoptic nucleus (SON) or anterior paraventricular nucleus/anterior commissural nucleus (PVN/ACN). The alpha-1-adrenergic agonist phenylephrine dose dependently increased plasma OT after injection into the SON or the PVN/ACN, and this was prevented by treatment with the specific alpha-alpha-1-adrenergic receptor antagonist prazosin, but not by the alpha-2 antagonist rauwolscine. The alpha-2-adrenergic agonist clonidine did not increase plasma OT. Injection of NPY or of the related peptide YY (PYY) alone into the SON or the PVN/ACN also dose dependently increased plasma OT; this was also significantly attenuated by prazosin. Plasma OT responses to NPY and PYY differed significantly in dynamics and duration, which may be related to large differences found in the patterns of displaceable binding of [125I]NPY and [125I]PYY to hypothalamic membranes. The stimulatory action of NPY was mimicked by a preferential Y-1 receptor agonist, but not by an agonist of the Y-2 NPY receptor. Coinjection of NPY or PYY and phenylephrine into either the SON or the PVN/ACN area produced a greater than additive discharge of OT, especially in the SON. This increase was mostly due to a markedly enhanced initial release of OT, and was also completely eliminated by prazosin. The NPY-alpha-1 interaction in stimulating plasma OT was not mediated by direct binding of the peptides to alpha-1-adrenergic receptor sites. These results indicate that 1) the stimulatory noradrenergic influence on OT secretion in the lactating rat is mediated by the alpha-1 adrenergic receptor via an action in the PVN/ACN and SON; 2) NPY also stimulates OT secretion in the lactating rat through the Y-1 receptor subtype in the PVN/ACN and SON; 3) NPY markedly enhances the OT secretory responses to alpha-1 receptor stimulation, particularly in the SON. The cooperative stimulation by NE and NPY may be of physiological importance in mediating the episodic release of OT in response to suckling.

Role of calcium in monitor peptide-stimulated cholecystokinin release from perifused intestinal cells.

Monitor peptide stimulates cholecystokinin (CCK) release from the intestine, but the cellular mechanisms responsible for this effect are uncertain. In the present study, the roles of membrane potential difference and calcium influx in monitor peptide-mediated CCK release were examined in a perifusion system containing isolated mucosal cells from the rat duodenum. This method represents an in vitro system in which CCK-releasing cells can be challenged with secretagogues or other maneuvers to study the dynamics of hormone secretion. High concentrations of KCl (50 mM), which reduce electrical potential difference across the cell membrane, caused the release of CCK. This effect was inhibited by the calcium channel blocker MnCl2. Monitor peptide stimulated CCK release in a dose-dependent manner at concentrations from 3 x 10(-12) to 3 x 10(-8) M. The requirement for extracellular calcium in secretagogue-stimulated release of CCK was investigated using ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA), a calcium chelator, and MnCl2. A calcium-free environment supplemented with 2 mM EGTA completely inhibited CCK secretion in response to stimulatory doses of monitor peptide. CCK secretion was restored when calcium was reintroduced into the system. Similarly, MnCl2 completely blocked monitor peptide-stimulated CCK release. These data indicate that membrane depolarization and monitor peptide stimulate the release of CCK through calcium-dependent mechanisms, suggesting that increases in intracellular calcium within CCK cells are likely to be important in CCK release.

Effect of drugs, hormones and electrical field stimulation on isolated muscle strips from human choledochoduodenal junction.

The behaviour of in vitro strips from the human choledochoduodenal junction would appear to be related to the anatomical location of origin of the strip. Strips from the papillary region showed low tone and obvious spontaneous rhythmic contractions (0 X 5-6/min). Strips from the region of the inferior choledochal sphincter showed, in ten out of fifteen specimens, spontaneous myogenic tone and gave a relaxation or a biphasic response (relaxation followed by contraction) to electrical field stimulation (0 X 3 ms pulses at 10 Hz for 5 s). All strips from human choledochoduodenal junction are remarkably insensitive to a variety of gastrointestinal hormones and to opioid agents.

Gastrointestinal hormones: central nervous system localization and sites of neuroendocrine actions.

It was established that VIP (vasoactive intestinal peptide), secretin, CCK (cholecystokinin), gastrin and motilin can be localized to the CNS by immunologic means. Whether or not these immuno-crossreactivities represent peptides identical to those in the g.i. tracts remains to be established. The neuronal localization of these five peptides in the gut predicted, however, their presence in neurons of the CNS. Furthermore, their presence within the hypothalamus and pituitary suggested physiological roles for these hormones in anterior pituitary function. We have now demonstrated the direct actions of VIP, secretin, gastrin and motilin on pituitary hormone release in vitro. Perhaps more importantly, we have described a hypothalamic site of action of VIP, secretin, CCK and gastrin to alter hormone release in vitro. Our data, taken in concert with those of other groups, suggest a modulatory role for the g.i. hormones and indicate the possible symphonic control by many hormones and transmitter candidates of distinct secretory events in the pituitary. Indeed, these data indicate the complexity underlying the finally tuned hypothalamus-pituitary-target tissue axis.

Effects of glucagon, Neurotensin, and vasoactive intestinal polypeptide on somatostatin release from perifused rat hypothalamus.

The effects of neuropeptides on the release of immunoreactive somatostatin (SRIF) from the rat hypothalamus were examined in vitro using a perifusion system. Twelve hypothalamic halves of male rats were placed on a Sephadex G-25 column and continuously eluted with Krebs-Ringer bicarbonate buffer, poH 7.4, at 37 C. A high potassium concentration (56 mM) stimulated SRIF release in a calcium-dependent manner. The infusion of glucagon (10(-7), 5 x 10(-7), and 10(-6) M) resulted in a dose-related increase in the release of SRIF. Neurotensin (10(-6) M) also stimulated SRIF release, whereas vasoactive intestinal polypeptide (10(-7) and 10(-6) M) inhibited SRIF release. SRIF release was not affected by cholecystokinin-octapeptide (10(-6) M), cholecystokinin-tetrapeptide (10(-6) M), or tRH (10(-6) M). These findings suggest that SRIF release from the rat hypothalamus is influenced by glucagon, neurotensin, and vasoactive intestinal polypeptide.

Effects of peripheral and central bombesin on feeding behavior of rats.

Intraperitoneal injections of tetradecapeptide bombesin (BBS) produced large, dose-related suppressions of liquid and solid food intake in rats, with threshold doses of 1--2 micrograms-kg-1. The feeding-associated behaviors of rats receiving BBS by this route at a test meal were normally sequenced, and several other observations suggested that the effect of BBS was specific and not due to malaise. The structurally related amphibian peptide litorin and the structurally related mammalian gastrin-releasing peptide (GRP) produced similar suppressions of food intake. The satiety effect of BBS administered intraperitoneally did not require the accumulation of food in the gut, the presence of intact adrenals, the abdominal vagus, or the release of cholecystokinin. When BBS and cholecystokinin were administered simultaneous, the suppressive effects on food intake were additive. Lateral cerebroventricular injections of BBS also produced large, dose-related suppressions of food intake, with a threshold dose of 100 ng per rat. The effect by this route, however, was not behaviorally specific: BBS produced equivalent inhibitions of food and water intake at every point on the dose-response curve, and produced a marked increase in grooming which dominated the behavioral display. Thus, (1) peripheral BBS is a putative satiety signal in the rat; (2) the class (endocrine, paracrine, or neural) and mechanism of this satiety action is not established; and (3) the differences in specificity and behavior following intraperitoneal and cerebroventricular routes indicate that peripheral BBS does not act solely via the cerebrospinal fluid to elicity satiety.

Vasoactive intestinal polypeptide stimulation of cyclic AMP formation in rat central nervous system.

Vasoactive intestinal polypeptide (VIP) stimulated cyclic AMP formation in the anterior pituitary, hypothalamus, pons and cerebral medulla of rat in vitro. The concentration of VIP above 10(-7) M significantly raised cyclic AMP level of these tissues with dose-dependency and the maximum stimulation of cyclic AMP formation was obtained at 5 min incubation. This stimulatory effect of VIP was not inhibited by propranolol or somatostatin. However, no enhancement of hormone release from the anterior pituitary or hypothalamus into the incubation medium by VIP was observed. These results suggest that VIP may act through adenylate cyclase in specific areas of rat central nervous system independent of beta-adrenergic receptor, but it may not necessarily be related to hormone release from the anterior pituitary or hypothalamus.

Vasoactive intestinal polypeptide (VIP)-sensitive adenylate cyclase in rat brain: regional distribution and localization on hypothalamic neurons.

The regional distribution of the vasoactive intestinal polypeptide (VIP)-sensitive stimulation of adenylate cyclase activity was studied in homogenates or rat brain. The order of sensitivity of this peptide on enzyme activity was: olfactory bulb > hippocampus > thalamus > occipital cortex congruent to frontal cortex congruent to midbrain congruent to hypothalamus > striatum > cerebellum congruent to brain stem > spinal cord. With neurotoxin-induced lesions the possible location of VIP-sensitive adenylate cyclase within the anterior hypothalamus was investigated. Intrahypothalamic 6-hydroxydopamine blocked the stimulatory effect of VIP on hypothalmic adenylate cyclase, but neither kainic acid nor 5,7-dihydroxytryptamine lesions had any effect. Similarly, there was a 71% reduction in the sensitivity of VIP-sensitive adenylate cyclase activity in animals whose hypothalamic noradrenergic innervation had been interrupted by transection of the ascending dorsal and ventral bundles. Biochemical analyses of the lesions suggested that loss of VIP action on adenylate cyclase was associated with loss of hypothalamic noradrenaline-containing neurons. These results may give insight into those regions of rat brain where VIP may have a neurotransmitter role, and point to a possible noradrenergic localization of the VIP-sensitive adenylate cyclase within the hypothalamus.