B. Glenn Stanley

The perifornical area: the major focus of (a) patchily distributed hypothalamic neuropeptide Y-sensitive feeding system(s)

Neuropeptide Y (NPY), a neurochemical found in high concentrations within hypothalamic neurons, is believed to participate in the control of eating behavior and body energy balance and elicits a powerful eating response when injected into the hypothalamus. To delineate precisely the locus of this effect, NPY (78 pmol) or its artificial cerebrospinal fluid vehicle was injected in the extremely small volume of 10 nl through chronic guide cannulae into an array of 47 different hypothalamic areas in satiated rats and the elicited food intake was measured. To determine the anatomical resolution of this technique, the spread and recovery of [125I]NPY injected in 10 nl was also assessed. Results indicate that as much as 95% of the injected label was recovered within the brain tissue and guide cannulae and that 100% of the tissue label was localized to within 0.8 mm of the injection site. Behavioral results show that the perifornical hypothalamus (PFH), at the level of the caudal paraventricular nucleus, is the most sensitive hypothalamic site for NPY-induced eating. NPY there elicited mean increases in food intake of 12.5 g over baseline at 1 h and 20.0 g at 4 h postinjection. Injections bracketing the PFH in all directions were substantially less effective. Additionally, significant effects were also observed in at least seven other sites that were distributed throughout the hypothalamus. These findings suggest both that the PFH may be the primary hypothalamic site containing feeding-related NPY-sensitive receptors and that other sites distributed within the hypothalamus also can mediate NPYs effects.

Multiple brain sites sensitive to feeding stimulation by opioid agonists: a cannula-mapping study.

Evidence suggests that brain opioid receptors of the mu, delta and kappa subtypes may be involved in the control of feeding behavior. However, limited information is available regarding the specific anatomical location of these feeding relevant opioid receptors. To address this problem, we microinjected three opioid agonists, morphine, (D-Ala2)-Met-enkephalinamide (DALA) or MR 2034, into one of 15 different brain areas and measured the subsequent feeding responses of satiated rats. Morphine (25 nmol) and DALA (6.8 nmol) both elicited strong feeding responses from the same five brain areas, namely, the paraventricular, dorsomedial and lateral hypothalamus, as well as from sites within the septum and amygdala. No other brain sites yielded significant responses to these opioid receptor agonists. In contrast to this anatomically specific pattern of effects, the opioid agonist MR 2034 (8.6 nmol) produced a feeding response which was generally smaller in magnitude and had little anatomical specificity. These findings suggest that opioid receptor systems for stimulating feeding exist in multiple discrete brain areas. Of the regions tested, specific sites within the hypothalamus, septum and amygdala are distinguished as being most sensitive to feeding stimulation by morphine and DALA.

Lateral hypothalamic injections of glutamate, kainic acid, D,L-α-amino-3-hydroxy-5-methyl-isoxazole propionic acid or N-methyl-D-aspartic acid rapidly elicit intense transient eating in rats

A convergence of evidence suggests that stimulation of lateral hypothalamic (LH) neurons can elicit eating, but the neurotransmitters that mediate this effect are unknown. To determine whether glutamate might be involved, it was injected through chronic guide cannulas directly into the LH of satiated adult male rats and consequent food intake was measured. Glutamate produced a dose-dependent eating response (mean intakes of 3.7 g at 300 nmol and 5.2 g at 900 nmol) only within the first hour after injection. As a first step in determining the receptor types mediating this response, agonists for specific excitatory amino acid (EAA) receptors were similarly tested. Kainic acid (KA), D,L-alpha-amino-3-hydroxy-5-methyl-isoxazole propionic acid (AMPA) or N-methyl-D-aspartic acid (NMDA) injected into the LH each elicited eating in a dose-dependent fashion beginning at 0.33 to 1.0 nmol. At maximally effective doses (1.0-33 nmol), each agonist elicited food intakes of approximately nine grams within 1 h. Finally, analysis of meal and behavioral patterns produced by LH injection of glutamate (600 nmol) and KA (1.0 nmol) revealed that the elicited eating usually began 2-3 min postinjection and consisted of a single normal to large size meal. There were no other behavioral effects during this initial postinjection period and no effects on other oral behaviors, like drinking or gnawing, at any time. Collectively, these findings suggest that glutamate may act through several subtypes of its receptors on some LH neurons to elicit eating.

Patterns of extracellular norepinephrine in the paraventricular hypothalamus: Relationship to circadian rhythm and deprivation-induced eating behavior

In order to clarify the physiological role of norepinephrine (NE) in the hypothalamic paraventricular nucleus (PVN), changes in extracellular levels of endogenous NE were measured in 11 freely-moving rats using microdialysis and high pressure liquid chromatography with electrochemical detection. To determine whether there was a circadian pattern of extracellular NE in freely-eating subjects, samples of dialysate from the vicinity of the PVN were collected and assayed for NE every 2 hrs for 48 hrs. The pattern of NE averaged across subjects was similar during both 24-hr periods, with a reliable peak at the beginning of the dark cycle and relatively stable levels at all other times. When these animals were subsequently deprived of food for 24 hrs, a gradual rise in extracellular NE was observed, ultimately increasing to 215% of the predeprivation level. When the animals were refed and NE measurements were continued at more frequent intervals, extracellular levels were found to decline during the first 20 min of eating, as well as over the next 3 hrs as food intake diminished. These patterns of extracellular NE, together with previous evidence, suggest that endogenous NE in the PVN plays a role in the initiation and/or maintenance of normal eating behavior at the beginning of the nocturnal feeding period, as well as after food deprivation.

Feeding responses to perifornical hypothalamic injection of neuropeptide Y in relation to circadian rhythms of eating behavior

Hypothalamic injection of neuropeptide Y (NPY) can elicit eating in satiated rats, and the perifornical hypothalamus (PFH) is the site where this effect is most pronounced (48). Additionally, there is a well-documented circadian rhythm of spontaneous eating behavior. Our objective was to determine whether there are daily rhythms of sensitivity to NPY in the PFH that might contribute to this behavioral rhythm. To accomplish this, the effectiveness in eliciting eating of PFH injection of NPY was examined at six different time points in the light-dark cycle. Neuropeptide Y (78 pmol/10 nl) or vehicle (10 nl) were injected through chronically implanted guide cannulas into the PFH of satiated adult male rats and food intake was measured 1, 2, and 4 h later. In animals on 12-12 h light-dark cycles, these injections were given 1 h before and after the onset of the light and dark phases, and in the middle of these phases. Additionally, dose-response effects of NPY were examined at two points: the first hour of both the dark and the light phases. The results show that NPY was effective at every time tested, and that the magnitude of the peptide-elicited intakes was primarily additive to the underlying patterns of spontaneous intake, with only a modest daily cycle of sensitivity to NPY. Consistent with this, NPY dose-dependently increased intake in the early light and in the early dark, and the magnitude of these effects across doses was similar at these times. This suggests that the sensitivity of the PFH system mediating NPY eating exhibits only a modest daily cycle.(ABSTRACT TRUNCATED AT 250 WORDS)

Catecholaminergic Control of Mitogen-Activated Protein Kinase Signaling in Paraventricular Neuroendocrine Neurons In Vivo and In Vitro: A Proposed Role during Glycemic Challenges

Paraventricular hypothalamic (PVH) corticotropin-releasing hormone (CRH) neuroendocrine neurons mount neurosecretory and transcriptional responses to glycemic challenges [intravenous 2-deoxyglucose (2-DG) or insulin]. Although these responses require signals from intact afferents originating from hindbrain CA (catecholaminergic) neurons, the identity of these signals and the mechanisms by which they are transduced by PVH neurons during glycemic challenge remain unclear. Here, we tested whether the prototypical catecholamine, norepinephrine (NE), can reproduce PVH neuroendocrine responses to glycemic challenge. Because these responses include phosphorylation of p44/42 mitogen-activated protein (MAP) kinases [extracellular signal-regulated kinases 1/2 (ERK1/2)], we also determined whether NE activates ERK1/2 in PVH neurons and, if so, by what mechanism. We show that systemic insulin and 2-DG, and PVH-targeted NE microinjections, rapidly elevated PVH phospho-ERK1/2 levels. NE increased Crh and c-fos expression, together with circulating ACTH/corticosterone. However, because injections also increased c-Fos mRNA in other brain regions, we used hypothalamic slices maintained in vitro to clarify whether NE activates PVH neurons without contribution of inputs from distal regions. In slices, bath-applied NE triggered robust phospho-ERK1/2 immunoreactivity in PVH (including CRH) neurons, which attenuated markedly in the presence of the α1 adrenoceptor antagonist, prazosin, or the MAP kinase kinase (MEK) inhibitor, U0126 (1,4-diamino-2,3-dicyano-1,4-bis[2-aminophenylthio]butadiene). Therefore, at a systems level, local PVH delivery of NE is sufficient to account for hindbrain activation of CRH neuroendocrine neurons during glycemic challenge. At a cellular level, these data provide the first demonstration that MAP kinase signaling cascades (MEK→ERK) are intracellular transducers of noradrenergic signals in CRH neurons, and implicate this transduction mechanism as an important component of central neuroendocrine responses during glycemic challenge.

Similar feeding patterns are induced by perifornical neuropeptide Y injection and by food deprivation

Although hypothalamic injections of neuropeptide Y (NPY) induce robust feeding, there is little information about the patterns of feeding elicited by this peptide. To reveal these patterns, NPY (0, 8, 24, 78, 235 pmol/10 nl) was injected into the perifornical hypothalamus (PFH) of satiated adult male rats and their subsequent food intake was monitored every minute for 24 h. For comparison, feeding patterns were similarly observed following fasts of 0, 3, 6, 9, 12, and 24 h. The results demonstrated that NPY and food deprivation both produced dose- or deprivation-dependent increases in food intake that were most evident in the first 6 h. The increased intakes induced by NPY were characterized by combinations of increased meal size and frequency, with the predominant effects being increases in the size of and decreased latency to eat the first meal. Similarly, fasting progressively increased food intake by combinations of increased meal size and frequency, with the predominant effects being increases in the size of and decreased latency to eat the first meal. These similarities between NPY-induced and food deprivation-induced feeding are consistent with a stimulatory role for endogenous NPY in deprivation-induced feeding. These findings also suggest that NPY may increase eating by acting on mechanisms of both meal initiation and of meal termination.

DMSO as a vehicle for central injections: tests with feeding elicited by norepinephrine injected into the paraventricular nucleus.

Dimethyl sulfoxide (DMSO) is becoming increasingly popular as a vehicle in studies employing central injections. The aim of the present study was to determine whether the vehicle required for solubilization of substances for central injection [75% DMSO and 25% artificial CSF (aCSF)] would alter the well-characterized stimulatory response to norepinephrine (NE) injected into the paraventricular nucleus (PVN) on short-term food intake. To evaluate its suitability, we compared the effects of repeated unilateral injections of NE dissolved in two different vehicles (100% aCSF or 75% DMSO, 25% aCSF), in separate groups of animals every 48 h over a 30-day period. NE (40 nmol) stimulated food intake by approximately sevenfold compared to either vehicle alone, and the stimulatory effect was similar whether aCSF or 75% DMSO was used as a vehicle. Furthermore, the NE-induced feeding did not vary in magnitude across a series of 13 tests. These results suggest that 75% DMSO is a suitable vehicle for administering NE (and likely other water-insoluble substances)in small volumes of 0.3 microl into specific brain regions.

Regional differences in feeding and other behaviors elicited by N-methyl-D-aspartic acid in the rodent hypothalamus: a reverse microdialysis mapping study.

Regional differences in the feeding stimulatory actions of hypothalamically delivered N-methyl-D-aspartate (NMDA) were investigated. NMDA (660 microM intraprobe) delivered by reverse microdialysis into the tuberal lateral hypothalamus (tLH) reliably elicited feeding in satiated rats. The average food intake was 8.6 g in 50 min, and during the infusion rats spent 26% of the time eating, compared to less than 1% before NMDA treatment. In contrast, NMDA did not affect feeding when reverse dialyzed into the anterior LH (aLH), posterior LH (pLH) or the medial hypothalamus (MH). NMDA had no apparent behavioral effect in the aLH; in contrast, it significantly decreased the time spent resting/sleeping when infused into each of the other three areas tested. Additionally, in the medial hypothalamus, NMDA infusions increased time spent grooming; while in the pLH only alertness was significantly increased. These data underscore the functional and anatomical heterogeneity of the hypothalamus, and implicate glutamate and NMDA receptors in different portions of the hypothalamus in the control of eating, grooming and arousal.

Lateral hypothalamic NMDA receptor subunits NR2A and/or NR2B mediate eating: immunochemical/behavioral evidence

Cells within the lateral hypothalamic area (LHA) are important in eating control. Glutamate or its analogs, kainic acid (KA) and N-methyl-D-aspartate (NMDA), elicit intense eating when microinjected there, and, conversely, LHA-administered NMDA receptor antagonists suppress deprivation- and NMDA-elicited eating. The subunit composition of LHA NMDA receptors (NMDA-Rs) mediating feeding, however, has not yet been determined. Identifying this is important, because distinct second messengers/modulators may be activated by NMDA-Rs with differing compositions. To begin to address this, we detected LHA NR2A and NR2B subunits by immunoblotting and NR2B subunits by immunohistochemistry using subunit-specific antibodies. To help determine whether NMDA-Rs mediating feeding might contain these subunits, we conducted behavioral studies using LHA-administered ifenprodil, an antagonist selective for NR2A- and/or NR2B-containing NMDA-Rs at the doses we used (0.001-100 nmol). Ifenprodil maximally suppressed NMDA- and deprivation-elicited feeding by 63 and 39%, respectively, but failed to suppress KA-elicited eating, suggesting its actions were behaviorally specific. Collectively, these results suggest that LHA NMDA-Rs, some of which contribute to feeding control, are composed of NR2A and/or NR2B subunits, and implicate NR2A- and/or NR2B-linked signal transduction in feeding behavior.Cells within the lateral hypothalamic area (LHA) are important in eating control. Glutamate or its analogs, kainic acid (KA) and N-methyl-d-aspartate (NMDA), elicit intense eating when microinjected there, and, conversely, LHA-administered NMDA receptor antagonists suppress deprivation- and NMDA-elicited eating. The subunit composition of LHA NMDA receptors (NMDA-Rs) mediating feeding, however, has not yet been determined. Identifying this is important, because distinct second messengers/modulators may be activated by NMDA-Rs with differing compositions. To begin to address this, we detected LHA NR2A and NR2B subunits by immunoblotting and NR2B subunits by immunohistochemistry using subunit-specific antibodies. To help determine whether NMDA-Rs mediating feeding might contain these subunits, we conducted behavioral studies using LHA-administered ifenprodil, an antagonist selective for NR2A- and/or NR2B-containing NMDA-Rs at the doses we used (0.001-100 nmol). Ifenprodil maximally suppressed NMDA- and deprivation-elicited feeding by 63 and 39%, respectively, but failed to suppress KA-elicited eating, suggesting its actions were behaviorally specific. Collectively, these results suggest that LHA NMDA-Rs, some of which contribute to feeding control, are composed of NR2A and/or NR2B subunits, and implicate NR2A- and/or NR2B-linked signal transduction in feeding behavior.