Aphagia and adipsia after preferential destruction of nerve cell bodies in hypothalamus

Lateral hypothalamic injections of glutamate, kainic acid, D,L-alpha-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.

Gastric mucosal erosions induced by lateral hypothalamic damage: neuronal and dopaminergic mechanisms

Electrolytic lateral hypothalamic (LH) lesions produce numerous disorders including aphagia, gastric mucosal erosions and autonomic and sensorimotor dysfunctions. This series of experiments examined whether damage to LH neurons or dopaminergic fibers of passage produce similar forms and severity of gastric erosions, as well as other disorders. In Experiment 1, LH neurons were destroyed by the excitatory neurotoxin, kainic acid, that presumably leaves axonal fibers of passage intact. Relatively selective damage to LH neurons with kainic acid produced glandular gastric erosions, as well as sensorimotor and autonomic dysfunctions similar to those seen following electrolytic LH lesions. This suggests that direct damage to LH cell bodies may be a primary cause of many of the disorders observed following LH lesions. In Experiments 2 and 3, electrolytic lesions were used to destroy cell bodies in the substantia nigra and their dopaminergic fibers (some of which pass through the LH area). This resulted in the production of gastric erosions in the absence of significant autonomic dysfunctions. Furthermore, atropine methylnitrate prevented the occurrence of gastric erosions following substantia nigra lesions, suggesting that the erosion formation is mediated via parasympathetic-vagal activity. In contrast, destruction of the ventral tegmental area (and its associated dopaminergic fibers) had no significant effect on gastric erosion formation. Experiment 4 showed that apomorphine, a central and peripheral dopamine agonist, provided protection against LH lesion-induced gastric erosion formation, whereas domperidone, a peripheral dopamine antagonist, had no effect. Taken together, this study suggests that (a) both LH neurons and fibers of passage provide a potential anatomical basis for the development of gastric mucosal erosions, (b) that an alteration in dopamine levels, either centrally or peripherally, may represent an important neurochemical mechanism for the development of erosions, and (c) that the occurrence of gastric erosion can be dissociated from other symptoms of the LH syndrome.

Modulation of lateral hypothalamic activity by olfactory bulb and sciatic stimulation

Lateral hypothalamic area (LHA) single unit activity (extracellular) was studied in response to electrical stimulation of the olfactory bulb (OB) or sciatic nerve in adult albino rats (n = 39) anesthetized with dialurethane. Olfactory stimulation resulted in a greater proportion of LHA units showing inhibitory rather than excitatory responses, while sciatic nerve stimulation resulted in similar proportions of units showing inhibitory and excitatory responses. Of the 76 LHA units tested with both OB and sciatic nerve stimulation, 36% responded to both stimulation sites, 18% responded only to OB stimulation, 26% responded only to sciatic nerve stimulation, and 20% were unresponsive to either stimulation. The locations of responsive units were diffuse throughout the LHA sampled. The response characteristics of LHA neurons to external sensory stimulation are consistent with the anatomy and putative integrative functions of this brain region.

Effect of lateral hypothalamic area lesions on serotonin-containing epithelial cells in rat duodenum

The aphagic effect of lateral hypothalamic area (LHA) lesions induced by kainic acid injection on serotonin (5HT)-containing epithelial cells in rat duodenum was studied in comparison with food deprived rats. The densities of 5HT cells were evaluated by quantitative morphometry using fluorescent histochemical longitudinal sections. The levels of 5HT/mg tissue were determined by HPLC on acid extracts of isolated villous epithelium. Body and duodenal weight losses, as well as duodenal mucosal atrophy, were comparable in the two groups of starved animals, i.e., one is food deprived and the other is lesioned animals. The numbers of 5HT cells in these starved groups were similar to those in controls so that the densities were increased. The 5HT/mg tissue in food-deprived animals was similar to that in controls but significantly higher in the LHA-lesioned group. These results are interpreted in terms of a possible central regulatory mechanism that is intact in the food-deprived animals but destroyed in the lesioned animals.

Hypothalamic sites affecting masticatory neurons in rats

The effects of hypothalamic electrical stimulation and dl-sulpiride injections on the unit activity of masticatory trigeminal neurons were assessed in rats. Unilateral electrodes or bilateral cannulas were implanted in the perifornical hypothalamus. The animals which exhibited eating to electrical stimulation or to sulpiride injections were selected. Then, under urethane anesthesia, electrical stimuli or sulpiride injections were applied at sites which elicited eating while a passive jaw movement-related neuron was recorded. Electrical stimulation or sulpiride injections affected the basal firing rate of 15 out of 32 (53%), and 13 out of 17 (76%) jaw movement-related neurons, respectively. The basal firing rate of 3 out of 18 (16.6%) was affected by electrical stimulation of noneliciting feeding nearby places. Facilitation was observed in 7 out of those 13 jaw movement-related trigeminal neurons after intrahypothalamic sulpiride injections. When dopamine was injected in the hypothalamus 3 minutes before sulpiride, this drug could only affect the basal firing rate of 1 out of 12 (8%) jaw movement-related neurons. The electrical stimulation and sulpiride injections into the hypothalamus had the same inhibitory or excitatory effect on a given trigeminal neuron as the passive jaw movement did. A similar phenomenon was observed with the sulpiride-induced facilitation. These results suggest that hypothalamic D2 satiety receptors modulate brain stem feeding reflexes.

Neurotoxic lesion of the mesencephalic reticular formation and/or the posterior hypothalamus does not alter waking in the cat

In order to re-evaluate the role of two putative waking systems, we injected a neural cell body toxin, ibotenic acid (IA) (45 micrograms/microliters), into the mesencephalic reticular formation (MRF) and/or the posterior hypothalamus (PH). On the one hand, when the cell body destruction was only restricted to the MRF, the IA microinjection was followed by a temporary high voltage and slow neocortical electroencephalogram (EEG) during the first 24 postoperative hours and by a subsequent long term increase in waking which lasted 8-12 h. After the first postoperative day, there were no motor disturbances, no aphagia nor adypsia, no alteration of cortical activation and no modification of thermoregulation or of the sleep-waking cycle. On the other hand, the IA microinjection into the PH induced a hypothermia during the first postoperative night and a dramatic transient hypersomnia immediately after the disappearance of the anesthesia (14-24 h after the IA injection). On the third day, all cats recovered control level of paradoxical sleep (PS), slow wave sleep (SWS) and cerebral temperature. They presented normal motor behavior but they were not able to eat by themselves during the first postoperative week. Finally, when the lesions of the MRF and the PH were realized in one single operation, the cats were first motionless in a comatose state for 2-3 days. This state was accompanied by a transitory hypothermia and the suppression of a spontaneous or evoked cortical low voltage fast activity. However, from the 2nd postoperative week, both behavioral and EEG waking re-occurred. By contrast, the two successive operations (MRF followed by PH) did not induce a comatose state. We did not observe any deficit in motor behavior, and the sleep-waking cycle was quite normal as from the second postlesion day. In the MRF-PH-lesioned cats, the injection of alpha-methyl-p-tyrosine (150 mg/kg) induced a large decrease in waking and a moderate increase in PS. In the MRF-lesioned cats, IA produced a large area of cell body loss, centered in the MRF, that extended from levels A2 to A6 of stereotaxic planes and sometimes encroached upon the red nucleus and the substantia nigra. In the PH-lesioned cats, the histological analysis revealed a great loss of cell bodies in the PH extended from levels A8 to A12.5. The damage included the lateral and posterior hypothalamic areas and sometimes the tuberomamillary nucleus. In MRF- and PH-lesioned cats, the cell body loss extended from levels A2 to A12.5.(ABSTRACT TRUNCATED AT 400 WORDS)

Glial changes following an excitotoxic lesion in the CNS--I. Microglia/macrophages

When an area of the adult rat CNS is depleted of neurons by an in situ excitotoxic injection, afferent axons to the area exhibit morphological alterations reminiscent of growth cones. These morphological changes are likely to be related to the deprivation of target cells. In addition, however, the area of neuronal loss is itself the site of profound changes in glial cell content, and altered axon-glial interactions may play a role in the axonal changes. In an attempt to define these interactions, we have undertaken a systemic study of glial populations in excitotoxically lesioned CNS over time. The microglial/macrophagic response is analysed in this paper; the astrocytic response is described in the companion paper [Dusart et al. (1991) Neuroscience 45, 541-549]. The microglial/macrophagic response was studied following kainic acid-induced neuronal loss in the thalamus of the adult rat. These microglial/macrophagic cells were labeled with the B4 isolectin from Griffonia simplicifolia, and the time-course of their response was studied between one day and one year post-lesion. This time-course study revealed different stages in the evolution of the response. At one day post-lesion, cell counts indicated that there was no increase in the number of non-neuronal cells in the neuron-depleted area. However, activated labeled cells were present in the entire thalamus on the side of the lesion, neuron-depleted or not. They were characterized by both increased lectin-binding and altered morphology when compared to quiescent microglia. In the absence of recruitment and/or proliferation, this result indicates that the early response consisted solely of the activation of resident microglia. By contrast, we observed a progressive increase in the number of non-neuronal cells in the lesion from four to 15 days post-lesion. A recruitment of blood-borne monocytes was apparent, and the observation of mitotic labeled cells indicated a proliferation of microglial/macrophagic cells in situ. There was a progressive decrease in the microglial/macrophagic reaction that began one month after lesion. In a thin band of parenchyma surrounding the neuron-depleted area, activated microglial/macrophagic cells were seen contacting neurons, and clusters of glial cells were observed around neurons up to one year post-lesion. These results suggest that neurons around the lesion site itself may be injured, secondarily, from a long term deleterious effect of the inflammatory process. This study allows us to conclude that activated microglia/macrophages are the predominant glial cell type in the excitotoxically lesioned CNS over the first weeks.(ABSTRACT TRUNCATED AT 400 WORDS)

Sex-dependent body weight changes after iontophoretic application of kainic acid into the LH or VMH

Body weight changes and food and water intakes were studied in CFY male and female rats after kainic acid (KA)-induced destruction of the lateral hypothalamic area (LH) or the ventromedial hypothalamic nucleus (VMH). To minimize the extent of damages, KA was iontophoretically applied by means of glass micropipettes. KA was ejected in 50 or 80 mM concentrations with 5-15 microA current for 5 min. Tip diameter of pipettes varied between 10-20 microns. Lesions were restricted to the LH or VMH. Effects were sex-dependent. LH lesions resulted in hypophagia, hypodipsia and body weight loss only in male rats. On the other hand, only female animals exhibited hyperphagia and weight increase when the VMH was destroyed. The role of sex-dependence in hypothalamic body weight regulation is discussed.

Dopamine in the lateral hypothalamus may be involved in the inhibition of locomotion related to food and water seeking

Experiments were conducted in male rats to assess the motor effects of bilateral intraperifornical microinjections of sulpiride, dopamine (DA) and other drugs. Sulpiride increased locomotion of the animals in all the experiments reported here. DA (10 micrograms) administered 5 minutes before sulpiride (8 micrograms) reduced the motor stimulant effect of the neuroleptic from 1601.3 +/- 337.6 to 742.5 +/- 180.4 counts/30 min. SCH 23390 (15 micrograms), haloperidol (2.5 micrograms) and atropine (18 micrograms) did not modify the locomotion level of animals acclimated to the actimeters. After carbachol (5 micrograms) the animals attained a level of hyperactivity (1459.5 +/- 146.5 counts/30 min) similar to that induced by sulpiride (1595.7 +/- 365.7 counts/30 min) in the same experiment. In other experiments DA (10 micrograms) administered 30 min before sulpiride again blocked the effect of 8 micrograms of sulpiride, and reduced the initial hyperactivity of food- and water-deprived animals previously familiarized with the actimeters (922.4 +/- 49.38 counts/15 min under saline, vs. 544 +/- 29 counts/15 min under DA). The same DA dose did not modify the initial spontaneous activity of nonfamiliarized nonfood-deprived rats (508.9 +/- 96.1 after saline vs. 520.9 +/- 47.1 after DA). These results suggest the presence of cells in the lateral hypothalamus involved in the control of locomotion. These experiments also suggest that locomotion triggered by the LH may be exploratory behavior essential to the search for water and food. As a corollary, DA in the LH appears to be involved not only in the inhibition of feeding and drinking but also in the inhibition of exploratory and food- and water-directed locomotion.

Excitotoxic lesions of the lateral hypothalamus made by N-methyl-d-aspartate in the rat: behavioural, histological and biochemical analyses

The purpose of this study was to determine whether the excitotoxin N-methyl-d-aspartate (NMDA) could be used to make lesions within the lateral hypothalamus and what effect they had on regulatory behaviour. Larger doses of NMDA were effective in the lateral hypothalamus but tended to spread into adjacent structures; smaller doses made lesions which were contained within the lateral hypothalamus and zona incerta. Lesions which damaged the lateral hypothalamus and surrounding tissue had no effect on the concentration of dopamine (or its metabolites) in the dorsal or ventral striatum. The large lesions, including extrahypothalamic damage, were associated with long-term deficits in lab chow and water intake, but rats with lesions restricted to the lateral hypothalamus made good recoveries, eating and drinking normally from around the tenth day post-operation. Body weight gain was normal in these rats, though there was a long-term loss of body weight compared to controls. Unoperated rats with food intake yoked to lesioned rats showed identical long-term changes in body weight, suggesting that the changes in body weight of lesioned rats may be a reflection of changes in eating and drinking rather than a disruption of a body weight set-point mechanism. Motor deficits were not found; all rats were able to consume without difficulty saccharin solutions. All lateral hypothalamic lesioned rats failed to respond to dehydrating, dipsogenic or glucoprivic challenges. It is concluded that NMDA is an effective toxin in the rat lateral hypothalamus, sparing ascending dopamine fibres, and that the main effect of such lesions is an impairment in responding to physiological challenges.

Central action of endogenous sugar acid (2-buten-4-olide): comparison with local anesthesia in hypothalamus

Rats were trained to discriminate cue tone stimuli (CTS) predicting reward (CTS+) [juice or intracranial self-stimulation (ICSS)], or aversion (CTS-) (mild electric shock or tail pinch). Unit activity in the lateal hypothalamus (LHA) and lateral preoptic-anterior hypothalamic area (lPOA-AHA) of the rat was recorded during CTS learning. The effects of local anesthesia of the amygdala (AM), ventral tegmental area (VTA) or LHA by procaine hydrochloride, and the effects of intraperitoneal or intravenous 2-buten-4-olide (2-B4O) on LHA neural activity and licking behavior were compared. LHA neurons differentiated between rewarding and aversive stimuli, and acquired corresponding discrimination of CTS+ and CTS-. In the lPOA-AHA, neurons responded similarly to CTS+, rewarding stimuli, CTS- and aversive stimuli. Procainization of the AM suppressed LHA neural responses to CTS1+ predicting juice, and stopped licking for juice. Procainization of the VTA suppressed LHA neural responses to CTS2+ predicting ICSS, and stopped licking for ICSS. LHA procainization suppressed both licking for juice and ICSS. Both intraperitoneal and intravenous 2-B4O stopped licking for juice and ICSS, but did not influence LHA responses to CTS1+ or CTS2+. The results suggest that dynamic interaction of AM-LHA-VTA are important for CTS+ learning, and 2-B4O acts directly on LHA neurons while maintaining afferent sensory inputs to the LHA.

Functional organization of striatum as studied with neural grafts

The function of the striatum has proved elusive. A structure which, at the gross microscopic level, appears homogeneous is now revealed to be heterogeneous in terms of its afferent and efferent relationships with cortex, limbic system and mid brain. Cerebral cortex projects topographically to caudate/putamen. Lesions to different cortical areas result in different behavioural impairments which are mirrored by selective neuronal or neurochemical lesions to the sectors of striatum receiving input from the cortex. Foetal neurones prepared from substantia nigra or striatum grafted to a damaged area of adult striatum reverse the lesion-induced behavioural impairments. Within different sectors of striatum the neurones and their afferent and efferent connections are defined to striosomes and matrix representing a finer grain of intrastriatal organization, the functional significance of which is unclear. It remains a challenge within such complex anatomical circuitry to discover the full extent of anatomical reintegration and functional compensation that can be achieved with grafts of foetal neurones.

Evidence for the presence of PNMT-containing cell bodies in the hypothalamus

The presence of intrinsic neurons in the hypothalamus containing the enzyme phenylethanolamine N-methyltransferase (PNMT), was investigated by selective destruction of the local cell bodies with kainic acid (KA), a potent excitotoxin. The unilateral stereotaxic injection of 2 micrograms of KA into the lateral hypothalamus produced a 30-35% decrease in the hypothalamic PNMT activity in the lesioned side compared with the contralateral uninjected side. The difference was statistically significant for up to 4 days after the lesion. The unilateral lesion did not have a unilateral effect on epinephrine or norepinephrine content as there was a significant reduction on both sides (50% for epinephrine and 30% for norepinephrine compared with saline injected). These data suggest the presence of intrinsic cell bodies in the lateral hypothalamus, containing the epinephrine-forming enzyme but lacking epinephrine storage sites. Our results support the previous hypothesis of the dissociation between epinephrine present in the hypothalamus and hypothalamic PNMT activity.

CNS connections with the median raphe nucleus: retrograde tracing with WGA-apoHRP-Gold complex in the rat

In this work we examined the neuronal input to one of the serotoninergic centers in the brain, median raphe nucleus (MR). Special consideration is given to projections of the hypothalamus. To describe the afferents to MR, a retrograde transport technique was used after microinjection of WGA-apoHRP-Gold complex under pressure and subsequent gold-silver intensification on formaldehyde-fixed rat brain sections. Optimal conditions were obtained when the coordinates of the injection site were A +/- 1.5, L +/- 0.15, and H +/- 2.7 according to Paxinos and Watson (The Rat Brain in Stereotaxic Coordinates. New York: Academic Press, '82). Results obtained under these conditions show a heterogeneous distribution of labeled neurons throughout the brain, including a large proportion (+/- 65%) of hypothalamic neurons. Extra-hypothalamic neurons projecting to MR were from the prefrontal cortex, lateral and medial habenular nuclei, the pontine area of the central grey, interpeduncular nucleus, dorsal raphe nucleus, oculomotor and trochlear nuclei, dorsal and laterodorsal tegmental nuclei, parabrachial nuclei, and lateral and interpositus cerebellar nuclei. Hypothalamic neurons connected to MR were found to be from medial and lateral preoptic areas, lateral hypothalamus, dorsomedian nucleus, the perifornical area, and the complex of mammillary bodies. Many other discrete regions contained different densities of labeled perikarya: the medial preoptic nucleus, paraventricular nucleus, retrochiasmatic area, arcuate nucleus, lateral magnocellular nucleus, and the posterior area. The MR appears as an integrative center receiving many neuroanatomically and functionally heterogeneous inputs from the whole brain.

Kainic acid lesions of the cat's midbrain periaqueductal grey region and emotional-defensive response evoked by carbachol injection to the same loci

Injections of carbachol (CCh) through a chronic cannula into the midbrain periaqueductal grey region (PAG) of the cat induced an emotional-defensive response (EDR) which was evaluated by duration and number of growls in a 30-min experimental session. That response was examined before and after injection of kainic acid (KA) to the same loci of midbrain. Injections of this excitotoxin into the PAG decreased EDR level. The degree of changes depended on the agent dose. A low KA dose (3 microgram/2 microliters) produced only prolongation of EDR latency, whereas a high dose of KA (6 micrograms/2 microliters) brought a statistically significant reduction of response level (reaching approximately 80%). The results have demonstrated the sensitivity of these cells of the PAG that are responsible for EDR.

Hypothalamic sites of neuronal histamine action on food intake by rats

To identify sites of histaminergic modulation of food intake, histamine H1-receptor antagonist was microinfused into the rat hypothalamus, the ventromedial hypothalamus (VMH), the lateral hypothalamus (LHA), the paraventricular nucleus (PVN), the dorsomedial hypothalamus (DMH), or the preoptic anterior hypothalamus (POAH), during the early light period. Feeding, but not drinking, was elicited in 100% of the rats (P less than 0.01) that were bilaterally microinfused with 26 nmol chlorpheniramine into the VMH. Unilateral infusion into the VMH did not affect food intake at doses of 26 or 52 nmol. Feeding was also induced by bilateral microinfusion into the PVN, but only the 52 nmol dose was effective. Bilateral infusions into the LHA, the DMH or the POAH did not affect ingestive behavior. Feeding induced by an H1-antagonist was completely abolished in all 7 rats tested when endogenous neuronal histamine was decreased by pretreatment with alpha-fluoromethylhistidine (100 mg/kg). The findings suggest that H1-receptors in the VMH and the PVN, but not in the LHA, the DMH or the POAH, may be involved in histaminergic suppression of food intake.

Effects of lateral hypothalamic lesions on the anorexia induced by ethanolamine-O-sulfate

Intracisternal (IC) injection of the GABA-transaminase inhibitor, ethanolamine-O-sulfate (EOS), has been previously shown to induce dose-dependent anorexia in normal rats as well as to reverse overeating in several rodent models of acute and chronic hyperphagia. To determine if such anorexia might be mediated by cells within or fibers of passage which traverse the lateral hypothalamus (LH), adult female rats received bilateral radiofrequency heat lesions of the LH vs. anesthesia control injections and were allowed to recover normal feeding and drinking responses. Using a longitudinal design, all animals then received 100, 0, and 200 micrograms EOS in 20 microliters deionized water IC with 1 week separating each injection. In addition to daily measures of feeding, drinking and body weight, all animals were screened 24 hr after injections for sensorimotor competence and general health by testing open-field activity, catalepsy, paw-lick responses on a hot-plate and rectal temperature. As reported previously, IC EOS induced dose-dependent hypophagia and weight loss. However, the magnitude and duration of these effects were equivalent in lesioned and control rats. In addition, open-field activity and body temperature were reliably lowered as a function of dosage while catalepsy was increased. Again, this effect was equivalent in lesioned and control rats. Subsequent tests of drinking and feeding in response to hyperosmotic and hypoglycemic challenges, respectively, confirmed that lesioned rats were deficient compared to controls. These findings suggest that an intact LH axis is not required for the anorexigenic effects of IC EOS.

Fetal homotypic transplant in the excitotoxically neuron-depleted thalamus: light microscopy

One month after an in situ injection of kainic acid into the ventrobasal thalamic complex (VB), the lesioned area is totally depleted of neurons. The present study has been undertaken to determine the cytoarchitecture and connectivity of the nucleus constructed by fetal thalamic neurons implanted into the excitotoxically lesioned area. Adult rats received an injection of kainic acid inducing a total neuronal depletion of the right lateral thalamus (including both the nucleus reticularis thalami and the lateral portion of the ventrobasal complex). One month later, homotypic neurons were taken from the dorsal thalamic primordium of rat embryos (gestational age 15-16 days), dissociated, and injected into the lesioned area as a cell suspension. After 2-4-month survival, the cytoarchitecture of the neonucleus formed by the grafted neurons within the previously neuron-depleted area was analyzed. Additionally, connectivity was analyzed in seven rats in which dorsal column nuclei and/or cortical projections to the area were labeled anterogradely with either 3H-leucine or wheat-germ agglutinin conjugated to HRP, and the animals were perfused and processed following various histological procedures (Nissl staining, autoradiographic processing, and histochemistry for visualization of peroxidase). Fetal neurons grew, differentiated, and progressively occupied the previously neuron-depleted area of the adult host CNS. They organized themselves into a neonucleus with particular cytoarchitectural features including 1) the existence of two concentric zones--a central zone containing neurons and glial cells and a marginal zone only filled with a band of glial cells, 2) an increase in cellular density compared to the intact thalamus, 3) the grouping of neurons in spherical clusters, and 4) apparent polymorphism of neuronal somata. Lemniscal and corticothalamic afferents originating from the host were observed in the neonucleus when the fetal neurons had been implanted correctly into the lesioned area but not when they had been misplaced into either normal thalamic tissue or the internal capsule. The afferents labeled from either the dorsal column nuclei or the somatosensory cortex were, however, less dense in the neonucleus than in the normal thalamus. These results are discussed with regard to the normal cytoarchitecture and connectivity of the ventrobasal complex of the rat thalamus.

Lateral hypothalamic feeding mechanisms: iontophoretic effects of kainic acid, ibotenic acid and 6-hydroxydopamine

In order to study hunger motivated behavior kainic acid (KA), ibotenic acid (IB) and 6-hydroxydopamine (6-OHDA) were iontophoretically applied to the lateral hypothalamus of rats. Neurotoxins at concentrations between 20-120 mMol were applied with 5-20 microA current for 5-10 min. Tip diameter of glass micropipettes varied between 10-50 micron. Application of KA, IB and 6-OHDA caused temporary body weight loss, hypophagia and hypodipsia. Effects were dose dependent: correlation was found between current strength, tip diameter of pipettes, concentrations of neurotoxins and the extent of cellular damage. Aphagic and adipsic symptoms and the death of animals were only observed after extensive LH lesions. There was no significant difference in food consumption after 24 hr deprivation among groups. Water deprivation and extracellular or intracellular dehydration resulted in a considerable increase in water intake in all animals, however, consumption in lesioned rats was lower than that of controls. These water regulatory disturbances in 6-OHDA treated animals were somewhat less severe. Results show that the bilateral cellular microlesions of the LH and damage of dopaminergic (DA) elements with 6-OHDA both cause disturbances of feeding behavior. Although the severity of symptoms in some respects depends upon the nature of neurotoxic treatment, the basic consequences are essentially similar. It is suggested that the LH "feeding center" and the ascending DA pathways represent a single system involved in the organization of hunger motivated behavior.

Internal and external information processing by lateral hypothalamic glucose-sensitive and insensitive neurons during bar press feeding in the monkey

Single neuron activities in the lateral hypothalamic area (LHA) were recorded during bar press feeding task in the monkey. First registered neurons were sorted into 2 groups, glucose-sensitive (GS) and glucose-insensitive (GIS) neurons, depending on their glucose sensitivity. The firing variations to feeding, electrophoretically applied catecholamines and opiate, and to odor and taste stimuli were investigated. GS neurons responded to dopamine, noradrenaline and morphine more often than GIS neurons. In feeding task GS neurons responded during bar press (BP) and reward (RW) periods with long-lasting inhibition of firing and at cue tone (CT) with transient inhibition, while GIS neurons responded during BP and RW periods mainly with excitation and at cue light (CL) with excitation. A majority of GS neurons responded to both odor and taste stimuli more often than GIS neurons. Data suggest that these two kinds of neurons in the LHA may be involved in different functional aspects of feeding: GS neurons, mainly in internal information processing and reward mechanism, and GIS neurons, in external information processing and motor aspects.

Lesions of the MPO or AV3V: influences on fluid intake

Electrolytic lesions in the MPO of rats had no significant effects on ad lib food and water intake, but impaired the drinking response to 1 M NaCl. Large MPO lesions also produced a persistent increase in plasma osmolality. In Experiment 2, we depleted neurons from the MPO of rats by iontophoretic application of the neurotoxin kainic acid (KA) which destroys nerve cell bodies without damage to fibers of passage. KA-induced neuron depletion in the MPO of rats significantly reduced the drinking response to 1.0 M saline, to 30% PG, and to 30 micrograms/kg isoproterenol. Ad lib water intake and drinking responses to food or water deprivation, to low concentrations (0.5 M) of hypertonic saline, to low concentrations (10% or 20%) of PG, and to systemic administration of 1.5 mg/kg angiotensin II were within the normal range. In Experiment 3, rats with electrolytic lesions that were strictly confined to the tissue immediately surrounding the wall of the anteroventral portion of the third ventricle (AV3V), without invading the MPO displayed normal ad lib food and water intake and plasma osmolality as well as drinking responses to water deprivation, hypertonic saline (0.5 or 1.0 M), angiotensin II (1.5 mg/kg) and isoproterenol (30 micrograms/kg).

Feeding and hypothalamic stimulation increase dopamine turnover in the accumbens

The hypothesis that the dopaminergic system plays a role in feeding behavior was tested in three experiments. First, microdialysis was performed in the nucleus accumbens (NAC) at 20 min intervals during free feeding in rats at 80% of normal body weight. Extracellular concentration of dopamine (DA), dihydroxyphenylacetic acid (DOPAC), and homovanillic acid (HVA) increased significantly during eating indicating an increase in DA turnover. Second, microdialysis samples were collected from the NAC during bar pressing with a) a signal light on and food available, b) the light on but no food available, c) neither light nor food. Only when food was available did extracellular DA, DOPAC and HVA increase significantly. This increase in DA turnover occurred in the accumbens but not in the ventral striatum. Third, electrical stimulation of the perifornical lateral hypothalamus (LH) that was capable of inducing feeding increased extracellular DA, DOPAC and HVA in the NAC. This occurred whether the animal had food to eat or not. The effect of LH stimulation on DA turnover resembled the effects of free feeding and operant feeding in Experiments 1 and 2. Perifornical LH stimulation did not increase dopamine turnover in the ventral striatum. The results show that perifornical LH stimulation activates the mesolimbic dopamine system and that dopamine release in the accumbens is involved in feeding. The increase in dopamine turnover outlasted the consummatory act. This suggests that accumbens dopamine may be related to sensory input, feeding reflexes, food reward or memory processes and not just to the consummatory act itself.

Depletion of neurons from preoptic area impairs drinking to various dipsogens

We depleted neurons from the lateral preoptic region (LPO) of rats by iontophoretic application of the neurotoxin kainic acid (KA). Rats with KA-induced damage to LPO neurons drank less water than controls after subcutaneous (SC) administration of: (a) 5 ml of a 1.0 M saline solution or (b) 5 ml of a 30% polyethylene glycol (PG) solution. The drinking response to 1.5 mg/kg angiotensin II (AII) was significantly smaller than was that of controls 15 min but not 1 hour after the SC injection. The experimental animals drank as much water as controls under ad lib conditions and showed normal drinking responses to low concentrations of hypertonic saline (0.5 M) or PG (10% or 20%).

Some anatomical observations on the projections from the hypothalamus to brainstem and spinal cord: an HRP and autoradiographic tracing study in the cat

The hypothalamus is closely involved in a wide variety of behavioral, autonomic, visceral, and endocrine functions. To find out which descending pathways are involved in these functions, we investigated them by horseradish peroxidase (HRP) and autoradiographic tracing techniques. HRP injections at various levels of the spinal cord resulted in a nearly uniform distribution of HRP-labeled neurons in most areas of the hypothalamus except for the anterior part. After HRP injections in the raphe magnus (NRM) and adjoining tegmentum the distribution of labeled neurons was again uniform, but many were found in the anterior hypothalamus as well. Injections of 3H-leucine in the hypothalamus demonstrated that: The anterior hypothalamic area sent many fibers through the medial forebrain bundle (MFB) to terminate in the ventral tegmental area of Tsai (VTA), the rostral raphe nuclei, the nucleus Edinger-Westphal, the dorsal part of the substantia nigra, the periaqueductal gray (PAG), and the interpeduncular nuclei. Further caudally a lateral fiber stream (mainly derived from the lateral parts of the anterior hypothalamic area) distributed fibers to the parabrachial nuclei, nucleus subcoeruleus, locus coeruleus, the micturition-coordinating region, the caudal brainstem lateral tegmentum, and the solitary and dorsal vagal nucleus. Furthermore, a medial fiber stream (mainly derived from the medial parts of the anterior hypothalamic area) distributed fibers to the superior central and dorsal raphe nucleus and to the NRM, nucleus raphe pallidus (NRP), and adjoining tegmentum. The medial and posterior hypothalamic area including the paraventricular hypothalamic nucleus (PVN) sent fibers to approximately the same mesencephalic structures as the anterior hypothalamic area. Further caudally two different fiber bundles were observed. A medial stream distributed labeled fibers to the NRM, rostral NRP, the upper thoracic intermediolateral cell group, and spinal lamina X. A second and well-defined fiber stream, probably derived from the PVN, distributed many fibers to specific parts of the lateral tegmental field, to the solitary and dorsal vagal nuclei, and, in the spinal cord, to lamina I and X, to the thoracolumbar and sacral intermediolateral cell column, and to the nucleus of Onuf. The lateral hypothalamic area sent many labeled fibers to the lateral part of the brainstem and many terminated in the caudal brainstem lateral tegmentum, including the parabrachial nuclei, locus coeruleus, nucleus subcoeruleus, and the solitary and dorsal vagal nuclei.(ABSTRACT TRUNCATED AT 400 WORDS)

Kainic acid lesions of the cat's antero-medial hypothalamus and emotional-defensive response evoked by carbachol injection to the same loci

Injections of carbachol (CCh) through a chronic cannula into the antero-medial hypothalamus (AMH) of the cat induced the emotional-defensive response (EDR) which was evaluated by time duration and number of growls in a 30-min experimental session. That response was examined before and after injection of kainic acid (KA) to the same loci of hypothalamus. None of KA doses employed (3 micrograms/2 microliter and 6 micrograms/2 microliter of vehicle) brought about statistically significant changes in parameters of the vocal response. The results suggest that either the AMH neuronal perikarya responsible for CCh-induced EDR, are resistant to KA, or muscarinic receptors initiating the EDR are not localized on perikarya.

Structural alteration and possible growth of afferents after kainate lesion in the adult rat thalamus

Afferents to the thalamic ventrobasal complex (VB) originating from the spinal cord, the dorsal column nuclei, and the somatosensory cortex were anterogradely labeled by WGA-HRP 30 days after an injection of kainic acid (KA), which produced a complete unilateral neuronal loss in the VB, the opposite side being used as a control. At the light microscopic level, there was no obvious rerouting of spinal afferents away from the lesioned areas towards unlesioned parts of VB. There was an apparent decrease in the number of lemniscal afferents to the lesioned side, which may indicate a progressive retrograde degeneration. At higher magnification, all three afferent systems studied demonstrated morphological changes, predominantly manifested by terminal swellings that reached up to 25 micron in diameter. Control experiments suggested that these morphological alterations were related neither to a direct action of the excitotoxin nor to the absence of a different afferent system but to the loss of neuronal postsynaptic targets. At the electron microscopic level, the normal ultrastructural features of VB were not observed after a KA lesion. No neuronal somata, dendrites, or normal presynaptic elements were observed. Neural elements, some of which were labeled from the somatosensory cortex or the dorsal column nuclei, were essentially of two types: varicosities and unmyelinated axonal profiles. Varicosities could be separated into two broad classes: The majority were large structures derived from large, sometimes myelinated, axons and containing a wealth of organelles. Since they were not completely surrounded by glial elements, we have denoted them unensheathed varicosities. Among the organelles, the most obvious features were vesicles and tubules of smooth endoplasmic reticulum, microtubules, mitochondria, and various lysosome-like inclusions. These unensheathed varicosities gave rise to large, mound-like protrusions containing large vacuoles and thin long protrusions either filled with neurofilaments or resembling unmyelinated axonal profiles. Others were completely surrounded by a glial sheet and were therefore called ensheathed varicosities. These ensheathed varicosities presented several characteristics typical of degenerating profiles, including neurofilamentous proliferation and morphological alterations of the mitochondria. Unmyelinated axonal profiles occupied a substantial territory in the lesioned area. They were most often grouped in bundles sometimes wrapped by glial processes.(ABSTRACT TRUNCATED AT 400 WORDS)

Convergence of signals in the zona incerta for angiotensin-mediated and osmotic thirst

Extracellular single-unit activity was recorded from 109 neurons in the diencephalon of urethane-anesthetized rats. Injections of angiotensin II (ANG II) into the subfornical organ (SFO) increased the activity of 15 zona incerta (ZI) neurons and decreased the activity of 9. Injections of ANG II into the SFO increased the activity of 8 lateral hypothalamic neurons and decreased the activity of 7. Of the units which responded to the injection of ANG II into the SFO, 9 neurons in the ZI and 5 in the lateral hypothalamus (LH) also responded to injections of hyperosmotic saline into the medial preoptic area. The SFO and preoptic area are possible sites of receptors for ANG II-mediated and osmotic thirst, respectively, and the present results suggest that signals important for the initiation of these thirst mechanisms converge on neurons in the ZI and LH. These findings are discussed in relation to other neural structures that have been implicated in the regulation of water intake.

Catecholaminergic mechanisms of feeding-related lateral hypothalamic activity in the monkey

The functional role of the catecholaminergic mechanism in the lateral hypothalamus (LHA), in feeding behavior of the monkey was investigated by single neuron activity recording and electrophoretic application of dopamine (DA), noradrenaline (NA) and their antagonists. The feeding paradigm had 4 phases: cue light (CL) signaled start of bar press; bar press (BP, 20-30 times); short cue tone (CT) triggered by last bar press signaled presentation of food; and ingestion-reward (RW). Of 312 neurons tested, 189 (61%) responded in one or more phases of the feeding task. Two types of response were observed: CL- or CT-related transient, and BP- or RW-related long-lasting responses. These feeding-related responses depended on the nature of the food and on the hunger-satiety level. DA excited or inhibited different neurons, while NA mainly inhibited firing. DA-sensitive neurons responded more often in the feeding task than insensitive neurons due mainly to differences in responsiveness to CL on (chi 2 test, P less than 0.01), at motor initiation, and during BP (P less than 0.05). Spiperone blocked the former two responses. NA-sensitive neurons responded more often in the feeding task due to responsiveness during BP and RW (P less than 0.01). Sotalol blocked some BP-related responses, and phenoxybenzamine and sotalol blocked the CT-related responses. The data suggest that dopaminergic and noradrenergic inputs in the LHA are crucial in task initiation and reward processing, respectively. Integration of these catecholaminergic and other inputs in the LHA might be important in accomplishing motivated feeding.

Amine accumulation in Parkinson's disease and other disorders

Amine accumulation in the axons of degenerating, amine-containing neurones is a natural component of neurone death in many species, including man. While it is becoming increasingly clear that this phenomenon may have functional significance in animal models of Parkinson's Disease, its potential importance in the clinical syndrome has been pretermitted. There are several reasons for this. Failure to sample tissue which contains accumulated amines, the masking of accumulation by adjacent depleted tissues and the degradation of accumulated amines in post-mortem tissues from Parkinsonian brains could account for the low incidence of detection of accumulation in this disorder. Increased levels of amines have been detected in the brains of patients with other conditions including cerebral infarction, Alzheimer's Disease and Huntington's Chorea. These increases have been attributed previously to enhanced aminergic activity, rather than a stage in the degenerative process, as our hypothesis suggests. In addition to the potential importance of amine accumulation in the pathophysiology of various clinical syndromes, a more thorough investigation of this phenomenon in animal models would seem essential since they are used routinely to both describe the basic principles of dopamine function and to evaluate therapeutic possibilities in Parkinson's Disease.

Neuronal responses in monkey lateral hypothalamus during operant feeding behavior

Single neuron activity was recorded from monkey lateral hypothalamus to investigate neuronal events correlated with operant bar press feeding behavior. The behavioral paradigm was divided into three phase: visual (discrimination), bar press (procurement), and ingestion (consummatory). Of 669 neurons tested, 158 (24%) responded in one or more phases. During the visual phase, 106 neurons (16%) responded. Of 80 neurons that responded in the visual phase and were tested systematically, 33 (41%, 33/80) responded selectively to the sight of food or nonfood objects associated with a juice reward, but not to the sight of nonfood or objects associated with aversive saline. Neuronal activity related to discrimination was modulated by satiation and learning (i.e., acquisition and extinction). During the bar press phase, 51 neurons (7.6%) responded. These responded tonically during the early or late stage of the bar press period, but did not depend on individual bar pressing motions. During ingestion, 90 neurons (13%) responded. The ingestion response was modulated by palatability of food and satiation. Data suggest that the LHA is deeply involved in operant feeding behavior; discrimination of food, drive to get food, and perception of reward, all of which are affected by learning and internal states such as hunger and satiety.

Neural projections subserving the initiation of a specific motivated behavior in the rat: new projections from the subfornical organ

The activation of neurons in the subfornical organ (SFO) by angiotensin II in the blood is known to stimulate thirst. The projections of these neurons were examined with anterograde and retrograde axonal transport methods, and were found to end in specific parts of the prefrontal cortex, septal region, substantia innominata, medial preoptic area, zona incerta and lateral hypothalamic area. These regions in turn are thought to be involved in arousal, somatomotor control and cognitive functions, essential components of the initiation and procurement phases of motivated behavior.

Visual responses related to food discrimination in monkey lateral hypothalamus during operant feeding behavior

Single neuron activity was recorded from monkey lateral hypothalamic area (LHA) to relate neuronal events to food discrimination and initiation of procurement movement in operant bar press feeding behavior. Of 429 neurons tested, 68 (16%) responded during visual phase. Of these, 30 (7%) responded selectively to the sight of food or non-food associated with a juice reward, but not to the sight of meaningless non-food or food associated with aversive saline. Neuronal activity related to discrimination was readily influenced by extinction, reversal or satiation. The strength of visual responses was correlated with latency of bar press initiation and speed of bar pressing, but was not related directly to bar press movement. These suggest that the LHA is deeply involved in discrimination of reinforcement or non-reinforcement, and might be associated with higher functions to regulate internal states such as physiological need to get food during operant feeding behavior.

Morphological changes of rat neurosecretory neurones after stereotaxic injection of kainic acid into the supraoptic nucleus or the supraoptico-hypophyseal tract

Kainic acid is a structural analogue of glutamic acid possessing neurotoxic property. In the present study, performed on rats, morphological changes of neurosecretory neurones after stereotaxic injection of kainic acid into the left supraoptic nucleus or into the left supraoptico-hypophyseal tract were investigated. It is shown that administration of kainic acid in a dose that leads to destruction of hippocampal pyramidal cells has no effects on supraoptic perikarya but does destroy neurosecretory axons. These results contradict the observations of many authors who reported that local injection of kainic acid into the brain causes degeneration of perikarya but leaves axons of passage unaffected.

Destruction of intrinsic neurons in the lateral hypothalamus disrupts the classical conditioning of autonomic but not behavioral emotional responses in the rat

The present study examined whether destruction of intrinsic neurons in the lateral hypothalamus of the rat would disrupt the acquisition of classically conditioned changes in arterial pressure. Ibotenic acid, a cellular toxin which spares axons of passage, was injected bilaterally in the hypothalamus either medial or lateral to the fornix. After 2 weeks the animals were subjected to classical fear conditioning trials involving the presentation of a tone in association with footshock. The next day changes in arterial pressure and emotional behavior elicited by the tone alone were measured. Destruction of intrinsic neurons in the lateral hypothalamus prevented the normal establishment of the arterial pressure conditioned response but did not affect the behavioral response. Unconditioned arterial pressure responses elicited by the tone and shock were not affected. Medial hypothalamic injections had no effect on any of the responses. The location of the lateral hypothalamic cell loss overlapped with the neurons projecting to the autonomic region of the spinal cord. Intrinsic neurons in the lateral hypothalamus therefore appear to be specifically involved in mediating learned cardiovascular adjustments.

Lateral hypothalamic innervation of the cerebral cortex: immunoreactive staining for a peptide resembling but immunochemically distinct from pituitary/arcuate alpha-melanocyte stimulating hormone

The combination of retrograde transport of fluorescent dyes and indirect immunofluorescence has been used to study the putative neurotransmitter specificity of the tuberal lateral hypothalamic projection to the cerebral cortex. Injections of either fast blue or diamidino yellow dye into the cerebral cortex or hippocampus retrogradely labeled large, multipolar neurons scattered through the lateral hypothalamic area and zona incerta at the level of the ventromedial nucleus of the hypothalamus. Approximately 80% of these neurons stained immunohistochemically with an antiserum against alpha-melanocyte stimulating hormone (alpha-MSH). A second population of smaller, predominantly bipolar alpha-MSH-like immunoreactive neurons was seen in the arcuate nucleus and retrochiasmatic area, but none of these projected to the cerebral cortex. Immunohistochemical staining for ACTH (18-24), another proopiomelanocortin series peptide, or with an antiserum against alpha-MSH (4-10) demonstrated only the second of these cell groups. Our results indicate that the tuberal lateral hypothalamic projection to the cerebral cortex contains a substance similar but not identical to alpha-MSH, and that this material is probably not derived from the same proopiomelanocortin precursor as true alpha-MSH.

Neurotoxic amino acid lesions of the lateral hypothalamus: a parametric comparison of the effects of ibotenate, N-methyl-D,L-aspartate and quisqualate in the rat

Separate groups of rats received unilateral lesions of the lateral hypothalamus by one of the 3 amino-acid neurotoxins, ibotenic acid (IBO), N-methyl-D,L-aspartic acid (NMA) or quisqualic acid (QA). A parametric comparison was made between the toxins on the extent of neuronal cell loss and the specificity of damage, by a systematic variation of both the volume (0.25-1.0 mm3) and concentration (0.03-0.12 M) injected. Neurotoxic potency on hypothalamic neurones varied in the order IBO greater than NMA greater than QA. All 3 toxins spared magnocellular supraoptic and accessory nuclei as well as medial hypothalamic neurones. Extrahypothalamic damage differed between the toxins: ventral thalamic neurones were susceptible to NMA and QA but only slightly to IBO, whereas the medial amygdala was sensitive to IBO but not NMA or QA. All 3 toxins spared ascending monoamine systems passing through the lateral hypothalamus, as assessed by biochemical assays of forebrain dopamine and serotonin. However, IBO induced a bilateral increase in dopamine levels, which was interpreted as an indirect consequence of the loss of lateral hypothalamic efferents projecting to the midbrain.

Organization of cerebral cortical afferent systems in the rat. II. Hypothalamocortical projections

The organization of hypothalamic projections to the cerebral cortex in the rat has been studied using retrograde and anterograde tracer methods. Four separate populations of hypothalamic neurons, which constitute a major source of diffuse cortical innervation, were identified: Tuberal lateral hypothalamic (LHAt) neurons which innervate the cerebral cortex tend to cluster in the perifornical region, in the zona incerta, and along the medial edge of the cerebral peduncle, at levels roughly coextensive with the ventromedial hypothalamic nucleus. Most of these neurons project to the ipsilateral cortex; a small percentage innervate the contralateral cortex, but this varies among cortical terminal fields. The perifornical neurons are organized in a roughly topographic medial-to-lateral relationship with respect to their cortical terminal fields. Field of Forel (FF) neurons, which project primarily to the frontal cortex of the ipsilateral hemisphere, are located just ventral to the medial edge of the medial lemniscus, at the level of the ventromedial basal thalamic nucleus. The more laterally placed neurons innervate the lateral frontal, insular and perirhinal cortex; the more medial neurons, around the mammillothalamic tract, innervate the medial frontopolar, prelimbic, infralimbic, and anterior cingulate cortex. Posterior lateral hypothalamic (LHAp) neurons form a dense cluster spanning the lateral hypothalamus, from the cerebral peduncle to the posterior hypothalamic area at premammillary levels, and extending into the supramammillary nucleus and the adjacent ventral tegmental area. LHAp neurons innervate the entire cerebral cortex, predominantly on the ipsilateral side. Populations of LHAp neurons projecting to different cortical target areas show considerable spatial overlap, but computer plots of the centers of these populations demonstrate a strict topographic relationship with respect to the cerebral cortex. Tuberomammillary (TMN) neurons form a sheet along the ventrolateral surface of the premammillary hypothalamus. About twice as many TMN neurons innervate the ipsilateral, as compared to the contralateral hemisphere; it is not known whether single neurons project to both hemispheres. No topographic organization of the TMN cortical projection is apparent. Injections of different-colored fluorescent dyes into various cortical areas demonstrate that hypothalamic neurons in general have rather restricted cortical terminal fields. Only occasional neurons are found, primarily in LHAt, which are double labeled by injections into different cytoarchitectonic areas.(ABSTRACT TRUNCATED AT 400 WORDS)

Striatal influence on ingestive behaviour in the cat

In freely moving cats with chronically implanted electrodes an analysis was made of the effects on feeding behaviour of low-frequency long-duration stimulation of the caudate nucleus, the substantia nigra and the globus pallidus. In all 3 structures a significant reduction of food intake was observed and in the pallidus this reached the point of a complete block of feeding. The effects were always limited to the period of stimulation. At the end of stimulation the animals recovered and took in food quantities equal to those of controls. The results are interpreted on the basis of reciprocal connections between the basal ganglia and the hypothalamus; the role of the striatum on the selection of certain movements and its possible involvement in behaviour is also discussed.

Amine accumulation in behavioural pathology

When nigro-striatal and meso-cortical neurons degenerate there is a loss of dopamine in the terminal fields and an accumulation of amines in the axons of these systems as they traverse the hypothalamus through the medial forebrain bundle. Traditional lines of thought have attributed the occurrence of motor and consummatory deficits which occur after dopamine neuron degeneration to the loss of functional dopamine neurotransmitter in the terminal fields. However, we have hypothesized that hypothalamic amine accumulation represents an area of brain tissue where processes such as neurotransmitter release, ephaptic transmission or local axon swelling may be affecting adjacent neurons and may thereby participate in the production of behavioural deficits. There is a considerable amount of evidence from studies on both peripheral and central catecholamine-containing neurons indicating that when their axons degenerate a release of functional neurotransmitter can occur. Information from neuropharmacological studies indicates that several drugs which facilitate behavioural recovery from dopamine-depleting lesions may do so by affecting amine release or receptor sensitivity near areas of accumulation rather than depleted terminal fields. We conclude that amine accumulation is a component of dopamine neuron degeneration which should be considered when assessing the role of the central catecholamine systems in the control of various behavioural and physiological processes.

Lateral hypothalamic self-stimulation persists in rats after destruction of lateral hypothalamic neurons by kainic acid or ibotenic acid

Bilateral injections of 1 microgram/microliter of kainic or ibotenic acid into the lateral hypothalamus (LH) of rats destroyed most of the cells in the LH. This treatment did not prevent electrical self-stimulation from electrodes placed in the LH, indicating that intrinsic neurons of the LH alone are not crucial elements of the neural system that mediates reinforcing hypothalamic stimulation.

Comparison of electrolytic and ibotenic acid lesions in the lateral hypothalamus

Electrolytic lesions in the lateral hypothalamus (LH) seriously affect ingestive behavior and sensorimotor functions in the rat. We here report that bilateral infusions of the neurotoxin, ibotenic acid (IBO) in the LH yield a decrease in body weight, but not to the same extent as electrolytic lesions. The sensorimotor impairments were most severe after electrolytic lesions. When tested in a residential maze on days 5-7 and 18-20 after surgery, both lesioned groups showed no lack of motivation to seek food and water. Histological examination of the LH following IBO exposure revealed extensive degeneration of neuronal cell bodies with little evidence of non-specific damage. Biochemical analysis of the rostral forebrain content of norepinephrine (NE) and serotonin (5-HT) revealed that the fibers passing through the LH remained largely intact in the IBO treated rats. The results suggest that the observed aphagia and adipsia is not due to a lack of motivation, but rather reflects changes in the process which operate to initiate eating and drinking. Furthermore, selective neuronal degeneration induced the same behavioral changes as the electrolytic ones, though not to the same extent.

Ibotenic acid lesions of the lateral hypothalamus: comparison with 6-hydroxydopamine-induced sensorimotor deficits

Three groups of rats received unilateral injections of ibotenic acid, 6-hydroxydopamine or vehicle control into the lateral hypothalamic area, and were given a range of tests of sensorimotor capacity. As expected from previous reports, the 6-hydroxydopamine injections induced a marked sensorimotor impairment to the contralateral side of the body. By contrast, the ibotenic acid injections produced no detectable sensorimotor changes, although the parameters and histological extent of the lesion were identical to those which produce aphagia, adipsia and sustained regulatory impairments when administered bilaterally. These results dissociate the classic electrolytic lesion of the lateral hypothalamus into homeostatic impairments following damage to intrinsic hypothalamic neurones, and sensorimotor impairments dependent only on damage to passing catecholamine fibre systems.

Angiotensin II immunoreactivity in the neural afferents and efferents of the subfornical organ of the rat

Angiotensin II (AII) immunoreactive cells and fibers were identified in the subfornical organ (SFO) of the rat. Cells were distributed in an annulus around the periphery of the SFO and were most visible in the Brattleboro rat treated with colchicine. Fibers were observed in a plexus, located centrally within the ring of cells, and knife-cuts suggested that they arise from parent cell bodies lying outside of the SFO. Studies combining immunohistochemistry with retrograde transport identified the perifornical zone of the lateral hypothalamus, the rostral zona incerta, and the nucleus reuniens of the thalamus as the source of AII-stained inputs to the SFO, and the region of the median preoptic nucleus as a recipient of AII-immunoreactive SFO efferents. It is suggested that these biochemically defined connections of the SFO participate in the central neural control of fluid balance.

A role for amine accumulation in the syndrome of ingestive deficits following lateral hypothalamic lesions

Lesions of the lateral hypothalamus produce ascending catecholamine neuron degeneration which results in terminal depletion and proximal accumulation above the lesions. The occurrence of deficits in ingestive behaviour has been attributed traditionally to the loss of functional dopamine neurotransmitter in the terminal fields. However, release of functional amines may occur in the lateral hypothalamus at areas of accumulation, to produce at least some of the behavioural symptoms characterizing the lateral hypothalamic syndrome. Recovery from behavioural deficits as a result of various pharmacological treatments, after dopamine-depleting lesions, may be mediated by changes in amine release or modified sensitivity of receptors affected by released amines. We conclude that amine accumulation should be considered when interpreting experiments implicating central catecholamine systems in the control of consumatory behaviour and the regulation of body weight.

Ibotenic acid lesions of the lateral hypothalamus: comparison with the electrolytic lesion syndrome

Rats received either ibotenic acid, electrolytic or sham lesions of the lateral hypothalamic area. Compared to sham operated rats, both lesion groups showed aphagia and adipsia following the lesion; this was less severe in the ibotenic acid lesioned rats. Once recovered, the ibotenic acid lesioned rats showed residual regulatory impairments in their compensatory responses to glucoprivation and to extracellular and intracellular dehydration. However, unlike the electrolytic lesioned rats, those with ibotenic acid lesions did not show akinesia and exhibited normal responses to both d-amphetamine and apomorphine. Ibotenic acid lesions resulted in extensive loss of cell bodies within the lateral hypothalamic area while sparing ascending dopamine neurones. The results are interpreted as suggesting that the lateral hypothalamic area and ascending dopamine neurones are components of a single system involved in the regulation of food and water intake.