Further mapping out of central noradrenaline neuron systems: projections of the "subcoeruleus" area

Regional topography within noradrenergic locus coeruleus as revealed by retrograde transport of horseradish peroxidase

A hitherto unsuspected degree of regional topographic organization in the noradrenergic nucleus, locus coeruleus, was revealed by the use of retrograde transport of horseradish peroxidase (HRP) from terminal areas receiving noradrenergic innervation. HRP was injected into hippocampus, hypothalamus, thalamus, caudate-putamen, septum, amygdala-piriform cortex, cerebellum and cortex. Successful transport was obtained from all areas, including the caudate-putamen and cerebral cortex. The pattern of HRP positive cells in the ipsilateral locus coeruleus was markedly different depending on the location of the HRP injection. Thus, hippocampal injections labeled cells in the dorsal locus coeruleus but not at all in the ventral tip. Injections of HRP into caudate-putamen or cerebellum labeled the ventral tip along with the rest of the dorsal portion. HRP injections into the septum labeled cells only in the dorsal half of the dorsal locus coeruleus. There thus exists a three tier division of locus coeruleus into the ventral one third, dorsal one third and intermediate one third. A further division was seen in the anterior-posterior plane with HRP injections into the thalamus labeling the posterior pole of locus very intensely but with little transport to more anterior levels; conversely HRP injection into the hypothalamus resulted in intense labeling only in the anterior pole of locus coeruleus. Amygdala-piriform cortex HRP injections revealed a further pattern with very intensely reactive cells scattered sparsely throughout the nucleus. Cortical HRP injections yielded weaker labeling also in occasional, scattered cells. All HRP transport to locus coeruleus was shown to be noradrenergic by degeneration with 6-hydroxydopamine and due to terminal, rather than fiber of passage, uptake by control injection into the dorsal NA bundle. It is concluded that the locus coeruleus is not an homogenous nucleus with respect to the origin of the noradrenergic projections to sundry forebrain, spinal and cerebellar areas but is comprised of distinct subdivisions of noradrenergic neurons.

Contribution of the locus coeruleus to the adrenergic innervation of the rat spinal cord: a biochemical study

The possible existence and magnitude of a noradrenergic innervation from the locus coeruleus (LC) to the spinal cord was investigated in the rat with various techniques. Horseradish peroxidase, injected into the lumbar spinal cord produced heavy labelling of presumably noradrenaline (NA)-containing neurons in the ventral region of the LC, while cells in the dorsal region of the LC were only lightly labelled. The effects of electrothermic destruction and electrical stimulation of the LC on levels of NA in various parts of the spinal cord, the cerebral cortex and the hippocampus were studied. Fourteen days after unilateral destruction of the LC there were decreases in NA levels of about 85% in the cerebral cortex and hippocampus and of about 15% in the cervical and thoracic segments of the spinal cord (ipsilateral versus contralateral). Fourteen days after bilateral lesioning of the LC significant decreases (about 25%) in NA levels were observed in all spinal cord segments. Unilateral stimulation in or near the LC induced decreases of NA levels in all areas of the central nervous system investigated. In this experiment the levels of NA in the spinal cord were significantly lowered in the ipsilateral cervical (16%), thoracic (12%) and lumbar/sacral (15%) segments of the spinal cord. These findings together indicate that a small part (no more than 30%) of the NA levels in the rat spinal cord are dependent upon the integrity and activity of NA-containing neurons of the predominantly ipsilaterally localized LC.

Origin and organization of brainstem catecholamine innervation in the rat

The catecholamine (CA) innervation of the rat brainstem was studied by biochemical analysis of discrete nuclei or areas and by glyoxylic acid-formaldehyde freeze dry fluorescence histochemistry. CA assays demonstrate that the highest norepinephrine (NE) content in brainstem is present in the trigeminal motor nucleus, nucleus tractus solitarius, dorsal motor nucleus of the vagus and nucleus raphe dorsalis. Bilateral locus coeruleus (LC) lesions do not significantly alter NE content in these nuclei but do decrease NE content in the superior and inferior colliculi, medial geniculate body, interpeduncular nucleus, pontine nuclei and the main sensory trigeminal nucleus (60-75%). Dopamine (DA) and epinephrine (E) are found in significant concentration in only a few of the nuclei examined. Fluorescence histochemical analysis indicates that two groups of NE axons innervate rat brainstem. LC neuron axons with a distinctive morphology principally innervate sensory and association nuclei of the brainstem. These disappear completely after bilateral LC lesions. The second group of axons originates from lateral and dorsal tegmental NE cell groups. Primary motor and visceral nuclei are densely innervated by fine and thick axons from these groups. Lesions of LC do not alter the NE innervation in any of the nuclei which contain axons of the second group. These results indicate that the brainstem NE innervation is divided into two major systems. The locus coeruleus complex innervates mainly primary sensory and association nuclei whereas the lateral tegmental NE neurons innervate primary motor and visceral nuclei. Although some overlap is present, the LC and lateral tegmental NE systems predominantly innervate separate and functionally distinct areas of the brainstem. DA and E neurons provide a very minor component of the brainstem CA innervation.

Effect of quipazine on brain stem monoamine neurons histofluorescence studies

Using two fluorescence histochemical methods, formaldehyde-induced fluorescence and sucrose-potassiumphosphate-glyoxylic acid fluorescence (SPG), we studied the effect of 5-hydroxytryptamine receptor stimulation by quipazine (2-[-piperazinyl]quinoline maleate) on monoamine fluorescence in the brain stem of rats. It was found that quipazine in a dose of 5 mg/kg i.p., after 60 min, decreased noradrenaline fluorescence intensity in noradrenergic neurons of the subcoeruleus area and diminished th density of catecholamine terminals visualized in the central part of the dorsal raphé nucleus. In the principal locus coeruleus, the intensity of fluorescence in nerve cells was not changed using either method, but with the SPG procedure, diffuse fluorescence outside cell bodies was observed after quipazine. In dorsal raphé neurons, a slight increase in 5-hydroxytryptamine fluorescence intensity was observed. The results obtained indicate that quipazine, apart from its effect on 5-hydroxytryptamine neurons, may also affect certain noradrenergic neurons.

Description of an indolaminergic cell component in the cat locus coeruleus: a fluorescence histochemical and radioautographic study

Using Falck-Hillarp fluorescence histochemical and radioautographic techniques, it has been found that, in addition to the well-known catecholaminergic cells, the locus coeruleus (LC) of the cat contains a sizeable component of indolaminergic neurons. Indolaminergic cell bodies occur in all subdivisions of the LC complex. They are most numerous in the LC proper and subcoeruleus area, but are also present in the medial and lateral parabrachial, and Kölliker-Fuse nuclei. In all, the indolaminergic cells are estimated to make up 7-10% of the monoaminergic neuronal population of the LC complex. With the exception of the Kölliker-Fuse nucleus, where somewhat larger cells occur, the indolaminergic cell bodies in different parts of the LC complex share a common fluorescence histochemical appearance. They display round to fusiform shapes and measure 30 x 18 micron on the average, which makes them cytoarchitectonically similar to the small type of noradrenergic cells in the LC. The formaldehyde-induced fluorescence of the indolaminergic cells in the LC complex was analyzed microspectrofluorometrically and the recorded excitation and emission spectra (maxima at 370 and 530 nm, respectively) were found to be identical with those recorded from midline raphe neurons. No evidence of noradrenaline content was found in the indolaminergic cells of the LC. Radioautographic experiments after intratissular injections of tritiated serotonin showed that the indolaminergic cells of the LC complex possess uptake mechanisms for serotonin. Taken together these results provide strong evidence for serotonin being the transmitter of the indolaminergic neurons discovered in the LC of the cat.

Specific uptake and retrograde flow of antibody to dopamine-beta-hydroxylase by central nervous system noradrenergic neurons in vivo

This study sought to determine whether the administration in vivo of antibody to dopamine-beta-hydroxylase (AD beta H) is taken up by central noradrenergic neurons and transported by retrograde flow to the cell bodies of origin. AD beta H serum or preimmune serum (control) in volumes of 1--20 microliter were stereotaxically injected into the lateral ventricle. Rats were sacrificed at times ranging from 1 h to 8 days. Cryostat sections were stained with fluorescein conjugated IgG. After 24 h, a bilateral granular fluorescence was seen only in neuronal cell bodies corresponding to noradrenergic cell groups A1--A7 with the most intense fluorescence localized within perikarya and processes of the locus coeruleus (A6) and subcoeruleus. This technique also permitted the visualization of the ascending dorsal and ventral noradrenergic bundles as well as varicose fibers and terminals in a pattern identical to that reported with histofluorescence, autoradiographic, biochemical and classical immunofluorescence techniques for the identification of noradrenergic fiber distributions. At 3 and 6 h, the first detectable fluorescence was observed in forebrain noradrenergic terminals and in fibers of the dorsal and ventral noradrenergic bundles. At 10 h fluorescent varicosities were first visualized within the caudal dorsal bundle and some cytoplasmic fluorescent particles were seen within locus coeruleus cell bodies. After 18 h locus coeruleus and subcoeruleus cell bodies were heavily stained, whereas medullary noradrenergic cell groups and nerve fibers were not labeled until after 24 h. An intense locus coeruleus fluorescence remained for 3 days and was completely absent after 6 days. Bilateral transection of the dorsal noradrenergic bundle in the rostral mesencephalon, at the time of injection, effectively blocked the retrograde transport of fluorescing material to the locus coeruleus. The overall staining pattern suggests that, in vivo, central noradrenergic fibers are capable of taking up antibody to dopamine-beta-hydroxylase. The ability of a dorsal bundle transection to abolish locus coeruleus staining, as well as the time course of AD beta H staining in noradrenergic neurons, suggests that AD beta H is transported via a rapid retrograde flow process. This technique combines retrograde transport of a marker protein with the sensitivity and specificity of immunocytochemical procedures to provide a new tool for the neuroanatomical study of neurotransmitter systems.

Analysis of feeding suppression produced by perifornical hypothalamic injection of catecholamines, amphetamines and mazindol

The effects on feeding of perifornical hypothalamic injection of catecholamines, amphetamines and mazindol were examined in hungry rats. In pargyline-pretreated subjects, both dopamine and epinephrine significantly suppressed food intake, at doses as low as 31 ng for dopamine and 150 ng for epinephrine (the latter injected with an alpha-adrenoceptor blocker). This effect was reliably strengthened by inhibiting catecholamine deamination or presynaptic catecholamine uptake. Perifornical injections of amphetamine, mazindol, methamphetamine, and phenmetrazine also suppressed feeding. The magnitude of this effect in individual animals was positively correlated with the effect produced by catecholamine agonists. Moreover, this effect of mazindol was partially antagonized by perifornical injection of dopaminergic and beta-adrenoceptor blockers. The effects of amphetamine and epinephrine were abolished by these drugs, while dopamine's effect was selectively inhibited by the dopaminergic antagonist. Serotonergic antagonists produced no change. These findings lend support to the hypothesis that perifornical hypothalamic catecholamine neurons, through dopaminergic receptors and beta-adrenoceptors, are involved in inhibiting feeding behavior, as well as in mediating the anorexic action of the amphetamines and mazindol.

Axonal transport of [3H]proteins in a noradrenergic system of the rat brain

Proteins synthesized from [3H]leucine injected into the rat nucleus locus coeruleus (LC) were transported through the hypothalamus in 5 successive waves at rates of 72-192, 24-48, 13-20, 3-4 and 1.4-2.9 mm/day (waves I through V, respectively). Waves I through IV began axoplasmic transport in the LC within the first few hours after [3H]protein synthesis began in the LC. Wave V was delayed in onset for 1.7-3.7 days and was also probably transported through the contralateral hypothalamus. Wave IV was not transported within the LC-hypothalamic axons ascending through the dorsal noradrenergic bundle since its transport was not blocked by 6-OHDA lesions in this bundle, as was transport of the other 4 waves. Unilateral dorsal bundle lesions caused a well defined caudal backup of dopamine-beta-hydroxylase immunofluorescence and a fall in dopamine-beta-hydroxylase activity in the ipsilateral frontal cortex and hypothalamus of 55% and 9%, respectively. Bilateral lesions caused only a significantly further reduction in hypothalamic levels indicating crossed innervation of the hypothalamus by the LC of 27%. Waves I and II have been classified as rapid transport and contained 33% of the transported [3H]protein. Wave V was slowly transported and contained 51% of the transported [3H]protein, while wave III was intermediate in rate and contained 16% of transported [3H]proteins.

Responses and pharmacological properties of preoptic/anterior hypothalamic neurones following medial forebrain bundle stimulation

1. The responses of neurones in the anterior hypothalamic and preoptic areas (POA/AHA) to stimulation of the medial forebrain bundle (MFB) have been studied in urethane anaesthetized female rats. Extracellular unit recordings have been made from 150 neurones which were responsive to a single stimulus applied to the MFB at the level of the mammillary nucleus. 2. Forty-five per cent of these cells were orthodromically activated with latencies ranging from 7.5 to 100 msec. However, the majority of cells responded with latencies of less than 40 msec. 3. Marked inhibition of spontaneous activity was observed in 41.5% of the units. Response latencies of up to 40 msec were observed in these cells, the inhibitory periods lasting up to 150 msec. 4. A small proportion of cells (13.5%) were antidromically activated and the average conduction velocity of these neurones in the POA/AHA with axons passing down to the mid-brain was estimated to be 0.3 m sec-1. It is suggested that they represent part of the descending MFB. 5. The experiments did not show any discrete topographical organization of cells in the POA/AHA which could be driven by MFB stimulation although the units tended to be located in more lateral rather than medial areas. 6. The responses to iontophoretically applied dopamine (DA) or noradrenaline (NA) was tested on sixty-one cells. These amines suppressed the activity of the majority of both orthodromically activated and inhibited units; the remaining cells were unresponsive. 7. These results provide electrophysiological evidence for both a direct and indirect input of MFB fibres to cells in the POA/AHA and that these inputs can be either excitatory or inhibitory. The data also indicate that a small number of fibres in the descending MFB originate from cells in the POA/AHA. 8. The sensitivity of these units to NA and DA suggests an inhibitory aminergic input, although this evidence is as yet indirect. 9. These connexions of the MFB, with neurones in the POA/AHA may be part of the neural circuits important for extra-hypothalamic modulation of gonadotrophin secretion.

Cerebellar inhibition and ICSS from stimulation in the area of the nucleus locus coeruleus

The purpose of this study was to determine the relationship between intracranial self-stimulation (ICSS) and the long-lasting inhibition (LLI) of cerebellar Purkinje cells which are produced by stimulation around the dorsal pontine nucleus locus coeruleus (LC). No strong correlation was found between the dorsal pontine sites which produced LLI and those sites which yielded ICSS. Moreover, ICSS sites were no more effective than non-ICSS sites in producing LLI. LLI of Purkinje cells was produced most effectively by stimulation of an area dorsolateral to the LC where axons arising from the LC collect to ascend to the cerebellum. The LLI produced by stimulation of this dorsolateral region was less often associated with short latency excitations, compared to the LLI produced by stimulation of the cerebellar white matter. This characteristic may be useful as an indication of LC-produced LLI. Sites yielding ICSS were scattered around the LC but were most consistent ventrolateral to the LC. These results indicate that ICSS and LLI of Purkinje cells appear to be independent phenomena which depend on different mechanisms.

Paraventricular nucleus: a primary site mediating adrenergic stimulation of feeding and drinking

Central injection of norepinephrine (NE) has been found to elicit preprandial drinking and feeding responses in the satiated rat. In the present study, 35 different brain areas, in over 500 rats, were examined to localize the precise region of NE sensitivity. Essentially all sites outside the hypothalamus, as well as in the lateral portion of the hypothalamus, were relatively or totally unresponsive to NE. In the medial hypothalamic area, the paraventricular nucleus (PVN) was clearly distinguished as the most effective site for initiating both feeding and drinking with noradrenergic activation in the satiated animal. Sites greater than 0.5 mm rostral, caudal, dorsal, ventral or lateral to this nucleus yielded significantly smaller effects. In mildly hungry rats, NE was found to potentiate the ongoing feeding response, and anatomical analyses of this phenomenon showed the PVN to be most responsive, with a smaller but reliable potentiation occurring along the periventricular hypothalamus adjacent to the third ventricle. Norepinephrine injected into the lateral perifornical hypothalamic area actually produced a suppression of feeding in these hungry animals. These findings, together with results from other studies, converge on the medial PVN region as being a key link in the process of increased food and water consumption associated with increased noradrenergic activity.

3H estradiol in catecholamine neurons of rat brain stem: combined localization by autoradiography and formaldehyde-induced fluorescence

3H setradion-17beta was localized in nuclei of catecholamine (CA) neurons of the rat lower brain stem, i.e., midbrain, pons and medulla, by employing a combined formaldehyde-induced fluorescence (FIF)-autoradiography approach which permits the direct visualization of 3H estradiol uptake in relation to CA-neuron perikarya and terminals. In the medulla, noradrenalin (NA)-containing neurons in and adjacent to the nucleus (n.) reticularis lateralis (group A1) and in the vicinity of the n. tractus solitarii (group A2) concentrated 3H estradiol. In the pons, NA neurons dorsal to the n. olivaris superior (group A5), in the locus ceruleus (group A6) and ventral to the pedunculus cerebellaris superior (group A7) displayed 3H estradiol uptake. In the midbrain, dopamine (DA)-containing neurons in the n. cuneiformis (group A8), in the zona compacta of the substantia nigra (group A9) and adjacent to the n. interpeduncularis (group A10), were not seen to concentrate 3H estradiol. This is in contrast to DA neurons in the n. arcuatus of the hypothalamus (group A12), previously reported to concentrate 3H estradiol. In addition, certain non-CA-containing neurons with nuclear uptake of 3H estradiol were observed to be surrounded by CA terminals in such areas as substantia grisea centralis, n. tractus solitarii and n. tractus spinalis nervi trigemini. This suggests a second mode of interaction between CA neurons and estrogen target neurons. The estradiol-CA neuron relationships described may provide morphological substrates underlying functional interactions between estradiol and CA neurons in the rat brain.

A new major projection from locus coeruleus: the main source of noradrenergic nerve terminals in the ventral and dorsal columns of the spinal cord

Almost all catecholamine (CA)-containing nerve terminals in the ventral column, intermediate grey and ventral half of the dorsal column disappeared after bilateral stereotaxic lesions of nucleus locus coeruleus, as revealed by fluorescence histochemistry. Some of the CA nerve terminals in the dorsal half of the column seemed to be unaffected by the lesions, as well as the CA terminals innervating the thoracic sympathetic lateral column and the band of nerve terminals crossing the midline and innervating the central grey. This coeruleo-spinal pathway in the rat is located in the anterior funiculus and the ventral parts of the lateral funiculus. A schematic map of the different CA projections to the spinal cord is presented. It was concluded that locus coeruleus innervates almost all parts of the central nervous system.

Ascending projections of the locus coeruleus in the rat. I. Axonal transport in central noradrenaline neurons

Axonal transport of protein and metabolites of L-[3H(G)]3, 4-dihydroxyphenylalanine ([3H]DOPA) was studied in the central noradrenaline neurons of the pontine nucleus locus coeruleus and was correlated with regional alterations of noradrenaline content following destruction of the nucleus. Unilateral lesions of the locus coeruleus produce a partial depletion of noradrenaline in the ipsilateral hypothalamus and telencephalon, indicating that these neurons project widely to the ipsilateral forebrain. Twenty-four to 48 h following local injections of 50 micronCi [3H]proline, locus coeruleus neurons take up labeled material and transport it, presumably as protein, to ipsilateral structures in the midbrain, diencephalon and telencephalon including the neocortex. Similarly 8 h after injection of 25 micronCi [3H]DOPA into the locus coeruleus, transport of material including catecholamines occurs to ipsilateral diencephalon and telencephalon. Axonal transport of proteins to telencephalic structures is greatly diminished by selective lesions of catecholamine terminals with 6-hydroxydopamine (6-OHDA) and following destruction of the medial forebrain bundle. These results provide further support for the view that noradrenaline neurons of the locus coeruleus nucleus project widely within the neuraxis to ipsilateral structures of the brain stem, diencephalon and telencephalon, including all cortical areas. In addition, evidence is presented for a contralateral projection with a similar distribution. The rate of axonal transport of labeled protein and metabolites of [3H]DOPA including [3H]catecholamines in central noradrenaline neurons is estimated to be 3-4 mm/h and is accordingly similar to that reported for noradrenaline neurons of the peripheral sympathetic nervous system.

Effects of locus coeruleus lesions upon cerebral monoamine content, sleep-wakefulness states and the response to amphetamine in the cat

The purpose of the present study was to investigate the effects of complete lesions of the noradrenaline locus coeruleus neurons upon wakefulness and paradoxical sleep. Radiofrequency lesions of the nucleus were performed in 8 chronically implanted cats which were continuously recorded with an EEG for 5 days prior to and 21 days following the lesions, when they were sacrificed. In 3 of these animals amphetamine (2 mg/kg) was administered on one control day and on the 10th day post-lesion. Following sacrifice, monoamine content was assayed in discrete brain regions, and the lesion was examined in Nissl-stained sections of the pons. (1) The majority (x 69%) of the locus coeruleus was bilaterally destroyed by the lesions which only minimally exceeded the boundaries of the nucleus within the dorsolateral pontine tegmentum. Noradrenaline was depleted by a mean of 85% in the paleo- and neocortex and by a mean of 60% in the thalamus and midbrain. (2) EEG activation reappeared within 12-48 h following the lesion and represented a normal percentage of recording time on the 3rd and subsequent days post-lesion. The behavioral arousal and long-lasting EEG activation produced by amphetamine was qualitatively and quantitatively the same pre- and post-lesion. (3) Despite alteration of certain components, paradoxical sleep reappeared within 48 h and recovered to normal amounts by the second week post-lesion. Muscle atonia was permanently absent in 7 animals. Ponto-geniculo-occipital (PGO) spiking was acutely redistributed across all states and chronically reduced in frequency (by a mean of 50%) within paradoxical sleep. These results indicate that the noradrenaline locus coeruleus neurons are not necessary for the tonic maintenance of EEG activation that occurs in normal wakefulness and in amphetamine-produced arousal. Furthermore, these neurons are not necessary for the occurrence of paradoxical sleep, although they may be involved in modulation of PGO spiking.

The catecholamine pontine cellular groups locus coeruleus, A4, subcoeruleus in the primate Cebus apella

The distrubution of CA neurons of areas A6 and A4 was delineated in Cebus apella monkey using the fluorescent histochemical technique of Falck and Hillarp. Cytospectroscopy was utilized for CA differentiation. The noradrenergic cellular regions A6, A4, and subcoeruleus have extensively increased in size in the Cebus as compared to the rat and appear to be separate nuclear regions. Area A4 is made up of two cellular subgroups: a more abundant lateral magnocellular area with cells as large as 45 mum and a smaller medial parvocellular group where the neurons are spindle-shaped and lie within 10-100 mum of the ependyma. The neuronal processes of A4 tend to be directed towards the flocculus and paraflocculus of the cerebellum. Some processes seem to enter the ependyma and others end subependymally. The functional significance of the pontine CA neurons is discussed.

The locus coeruleus: a cytoarchitectonic, Golgi and immunohistochemical study in the albino rat

The locus coeruleus of the adult albino rat is a clearly delimited nucleus in Nissl-stained preparations. It is surrounded by an extensive, relatively neuron-free neuropil which is not stained in reduced silver and Luxol fast blue preparations. Most if not all locus coeruleus neurons contain the enzyme dopamine-beta-hydroxylase (DBH) and are thus presumably adrenergic. Two general classes of medium-sized neuron were found in the locus coeruleus in Nissl- and DBH-stained material: multipolar and somewhat smaller fusiform cells. The nucleus was divided into dorsal and ventral parts cytoarchitectonically; the two are distinguished in that (a) fusiform rather than multipolar cells predominate in the dorsal division, (b) cells in the dorsal division are more densely packed, and (c) a majority of the cells in the dorsal division are aligned obliquely in a dorsolateral to ventromedial orientation when viewed in the frontal plane, and longitudinally (anteroposteriorly) when viewed in the horizontal and sagittal planes. The locus coeruleus contains an estimated 1643 +/- 21 neurons (+/- S.E.M.; N=12) as determined in Nissl-stained paraffin sections, and 1439 +/- 29 neurons (+/- S.E.M.; N=6) as determined in DBH-stained frozen sections. The latter estimate is less reliable because of some uncertainty about section thickness. The ventral division of the locus coeruleus has an estimated 210 +/- 11 neurons (+/- S.E.M.; N=6). In Golgi-Cox material counterstained with cresyl violet most locus coeruleus neurons could also be classified as multipolar or fusiform, the latter being somewhat smaller. Typically, both types of neuron have relatively long thin dendrites which branch once or twice and extend well beyond the limits of the nucleus into surrounding neuropil and nuclear areas, particularly the mesencephalic nucleus of the trigeminal nerve and pontine central gray. Spines, consisting of a thin stalk of variable length with a small bulb at the end or just a thin stalk, were scattered infrequently but regularly along all dendrites and a majority of the somata of both classes. Very thin locally ramifying axon-like plexuses were impregnated in several locus coeruleus neurons, as were larger (about 3 mum diameter) projecting axons. Only about 0.07% of the locus coeruleus neurons were impregnated in the Golgi-Cox material although a wide range of impregnation times and ages was used.

Responses of primate locus coeruleus and subcoeruleus neurons to stimulation at reinforcing brain sites and to natural reinforcers

In alert rhesus monkeys the activity of 64-neurons was recorded in the locus coeruleus and subcoeruleus region, collectively referred to as coeruleus (C) neurons. C neurons were identified physiologically by antidromic activation from electrodes in the medial forebrain bundle (MFB) and medial septal nucleus which sustained intracranial self-stimulation (ICSS) behavior, and/or anatomically by their proximity to microlesions at unit recording sites. The following results were obtained: (1) the current intensity that supported the highest rate of MFB and septal ICSS was similar to the current intensity for evoking antidromic responses in C neurons; (2) stimulation in the vicinity of the dopaminergic neurons of nucleus A10 did not activate C neurons; (3) C neurons were antidromically activated by ipsilateral and contralateral MFB shocks; (4) the C axons had slow estimated conduction velocities (1-5 m/sec), and a mean neural refractory period of 0.8 msec; (5) the behaviorally determined refractory period for MFB ICSS was also approximately 0.8 msec; and (6) mean firing rates while the monkey sat quietly were 15 +/- 2 Hz (S.D.) for subcoeruleus cells and 5 +/- 3 Hz for locus coeruleus cells, and activity of most cells changed negligibly during operant responding for apple-sauce reinforcement. These results suggest that the reinforcing effects of ICSS may be mediated by activation of coeruleus cells, but that these cells do not appear to be strongly involved in operant responding for natural reinforcers.

Midbrain, diencephalic and cortical relationships of the basal nucleus of Meynert and associated structures in primates

The structure and connectivity of the basal nucleus of Meynert, the substantia innominata in which it lies, and certain related areas have been examined in New World and Old World Monkeys, using retrograde and anterograde axonal transport methods. Experiments using the retrograde, horseradish peroxidase method confirm the observations of Kievet and Kuypers ('75) that the basal nucleus and substantia innominata project directly, heavily and with a somewhat crude topography upon the neocortex. Experiments involving the anterograde, autoradiographic method show that the basal nucleus and substantia innominata form part of a complex pathway that links them together with the lateral hypothalamus, certain parts of the amygdala and the peripeduncular nucleus of the midbrain. The peripeduncular nucleus is often regarded as a part of the central auditory pathway; it gives rise to a fiber bundle of considerable size that ascends on the dorsal surface of the ipsilateral optic tract and terminates ultimately in the lateral hypothalamic area of both sides. As well as distributing fibers to the basal nucleus, substantia innominata and lateral hypothalamus, this pathway provides a heavy projection to a cytoarchitectonically distinct posterior part of the lateral nucleus of the amygdala, the medial and intercalated nuclei of the amygdala and a less dense projection to the bed nucleus of the stria terminalis. Certain parts of the hypothalamus and possibly the preoptic areas give rise to a complementary descending pathway that distributes fibers to the ipsilateral basal nucleus, substantia innominata and amygdala, and ends in the peripeduncular nuclei of both sides. Decussating fibers in both the ascending and descending pathways cross in the ventral supraoptic commissure. It is concluded that the basal nucleus should include most of the aggregated and unaggregated large cells that lie in the substantia innominata and which in places intrude upon the preoptic regions and the nucleus of the diagnonal band of Broca. Together, these may form a complex that receives inputs from a variety of brainstem sources, and projects widely and diffusely upon all cortical structures of the telencephalon.

Changes in the metabolism of hypothalamic norepinephrine associated with the onset of maternal behavior in the nulliparous rat

Both norepinephrine (NE) and its major metabolite, 3-methoxy-4-hydroxyphenylglycol (MHPG), were assayed both in the hypothalamus of nulliparous rats that had behaved maternally toward foster young and in the hypothalamus of those that had failed to behave maternally. It was found that the maternally-behaving animals had both lower concentrations of NE and higher concentrations of MHPG as compared with their nonresponding counterparts. These data parallel those reported for the puerperal female and suggest that the onset of maternal behavior may be mediated by increased transmission across hypothalamic noradrenergic synapses.

Time-course variations in tyrosine hydroxylase activity in the rat locus coeruleus after electrolytic destruction of the nuclei raphe dorsalis or raphe centralis

Time-course variations in tyrosine hydroxylase activity were measured in the locus coeruleus of the albino rat after electrolytic coagulation of either the nucleus raphe dorsalis or the nucleus raphe centralis. Highly significant increases were measured at 4 days after lesioning of the raphe dorsalis (30.33%) and the raphe centralis (81.55%) compared with control values, whereas the activity in groups A9 and A10 was unchanged at this time-point. In conjunction with other experimental evidences, an hypothesis is proposed that the catecholaminergic neurons located in the locus coeruleus are directly and/or indirectly controlled by the serotonin-containing neurons located in the anterior raphe system nuclei.

Brain stem self-stimulation attenuated by lesions of medial forebrain bundle but not by lesions of locus coeruleus or the caudal ventral norepinephrine bundle

Midbrain tegmental intracranial self-stimulation (ICSS) was not attenuated by ipsilateral or bilateral locus coeruleus lesions. Certain of these lesions were followed by histochemical confirmation that the majority of locus coeruleus neurons was destroyed, and biochemical evidence that over 80% of the cortical norepinephrine was depleted. To test the possibility that the surviving ICSS was due to stimulation of another norepinephrine system, histochemically verified ipsilateral or bilateral lesions of the ventral norepinephrine bundle were administered to a second group of midbrain tegmental ICSS animals. These lesions resulted in marked loss of body weight, but had no effect on ICSS. In a third experiment, lesions were made in the medial forebrain bundle (MFB) ipsilateral to midbrain tegmental ICSS electrodes. These lesions resulted in attenuation of ICSS which was directly proportional to the extent of MFB damage. On the basis of these data alone, however, it was not possible to identify the ciritical fibers supporting ICSS. It was oncluded that the locus coeruleus does not play a necessary role in midbrain tegmental ICSS.

Catecholaminergic mechanisms of the lateral hypothalamus: their role in the mediation of amphetamine anorexia

The brain mechanisms mediating amphetamine's suppressive effect on feeding behavior were analyzed in rats with chronically implanted brain cannulas. Experiments in which drugs were injected directly into the anterolateral hypothalamus, the region found to be most responsive to amphetamine's action, yielded the following results. (1) Over a dose range of 6.25 nmoles (0.8 mug) to 400 nmoles (51.4 mug), hypothalamically injected D-amphetamine produced a reliable suppression of food consumption (20 percent at 6.25 nmoles, increasing to 88 percent at 200 nmoles) and was found to be approximately 3 times as potent as L-amphetamine in yielding this effect. (2) The anorexic effect of hypothalamically injected D-amphetamine was totally abolished by local administration of alpha-methyltyrosine, an inhibitor of dopamine, norepinephrine, and perhaps epinephrine synthesis, or by local administration of Fla-63, an inhibitor of only norepinephrine, and perhaps epinephrine, synthesis. (3) This effect of hypothalamic D-amphetamine was also antagonized by locally administered dopaminergic or beta-adrenergic receptor blockers but was unaffected by alpha-adrenergic, serotonergic, and cholinergic blockers. (4) Lateral hypothalamic administration of dopaminergic or beta-adrenergic receptor blockers, at quite low doses, was also effective in antagonizing the anorexia induced by peripherally administered D-amphetamine. These results strongly suggest that amphetamine, in suppressing feeding behavior, acts through the lateral hypothalamus, perhaps the anterior region, causing a release of dopamine and norepinephrine (or perhaps epinephrine) from lateral hypothalamic nerve endings and a subsequent stimulation of dopaminergic and beta-adrenergic receptors located in that region.

The central adrenergic system. An immunofluorescence study of the location of cell bodies and their efferent connections in the rat utilizing dopamine-beta-hydroxylase as a marker

A sensitive immunofluorescence technique was used to describe systematically the distrubution of dopamine-beta-hydroxylase (DBH)-containing cell bodies, non-terminal fiber pathways, and terminal fields in the brain of the male albino rat. DBH is the enzyme that catalyzes the conversion of dopamine to noradrenaline, and as such is useful as an anatomical marker for noradrenaline and possibly adrenaline neurons. The enzyme is not present in dopamine- or indolamine-containing neurons. Ten micron frozen sections (1-in 20 series) were prepared in the frontal, sagittal, and horizontal planes from the olfactory bulb to the upper cervical segments of the spinal cord; adjacent sections in each plane were stained for DBH and for cells (toluidine blue=azure II). An atlas consisting of 40 projection drawings of selected frontal sections illustrates the results of the investigation. DBH perikarya are confined to three groups in the pons and medulla: the well defined locus coeruleus, a more diffuse but continuous subcoeruleus group that arches through the pons and ventral medulla, and a third dorsal medullary group centered in the dorsal motor nucleus of the vagus. A single principal adrenergic fiber system distributes a great many of the axons from these neuron groups to a majority of nuclear areas in the brain. In the pons and medulla two components of the fiber system may be distinguished. A medullary branch may be followed from the posterior aspect of the subcoeruleus group dorsally and then anteriorly through the lateral tegmental field and ventral aspect of the vestibular complex to a position subjacent to the locus coeruleus, where it is joined by a subcoeruleus branch consisting of a large number of fibers coursing among cells along the length of the subcoeruleus group, and by fibers arising from the locus coeruleus. Anterior to the locus coeruleus the principal adrenergic bundle courses as a single fiber tract immediately ventrolateral to the central gray in the mesencephalon and in the zona incerta and substantia innominata in the diencephalon. At the level of the septal area separate bundles reach the cortex dorsally over the genu of the corpus calosum via the medial septal-diagonal band nuclei and the lateral septum and ventrally between the olfactory tubercle and caudate-putamen. In the medulla and pons adrenergic fibers undoubtedly course in both directions. Anterior to the most rostral pontine cell bodies, however, all fibers presumably ascend. Along the course of the bundle distinct branches emerge to innervate circumscribed terminal fields. In addition, certain regions of the brain such as the reticular formation and pontine gray receive diffuse DBH innervation derived from less clearly defined pathways. A small number of areas in the brain contain little or no detectable DBH. These include the caudate-putamen, nucleus accumbens, globus pallidus, olfactory tubercle, subthalamic nucleus, substantia nigra, pretectal area, third, fourth and sixth cranial verve nuclei, and the trapezoid body nucleus.