Subdivisions and neuron types of the nucleus of the solitary tract that project to the parabrachial nucleus in the hamster

The solitary nuclear complex (NST) consists of a number of subdivisions that differ in their cytoarchitectonic features as well as in the amounts of inputs they receive from lingual afferent axons. In this study horseradish peroxidase (HRP) was injected into the parabrachial nucleus (PBN) of the hamster to determine which of these subdivisions contain cells that project to the pons. In the rostral, gustatory division of the NST, the rostral central subdivision contains the greatest number of labelled pontine-projection neurons. The rostral lateral subdivision contains moderate numbers of labelled cells; progressively fewer labelled cells are in the ventral, medial, and dorsal subdivisions. In the caudal, general viscerosensory division of the NST, the caudal central subdivision contains the majority of labelled cells, although fewer than its rostral counterpart. Progressively fewer cells are labelled in the medial, laminar, ventrolateral, and lateral subdivisions; none in the dorsolateral subdivision. Small horseradish peroxidase injections into the pons revealed that cells of the rostral central and rostral lateral subdivisions of the NST project to the medial subdivision of the PBN, predominantly to caudal and ventral parts of the subdivision. Cells of the caudal central and medial subdivisions of the NST project to the central lateral subdivision of the PBN, predominantly to intermediate and rostral-dorsal parts of the subdivision. Outside the NST, cells in the spinal trigeminal nucleus and parvicellular reticular formation were also labelled after PBN injections. Within the rostral central and rostral lateral (gustatory) subdivisions of the NST at least two types of neurons, distinguished on the basis of dendritic and cell body morphology, were labelled after HRP injections that included the medial PBN. Elongate cells have ovoid-fusiform somata and dendrites oriented in the mediolateral plane parallel to primary afferent axons entering from the solitary tract. Stellate cells have triangular or polygonal cell bodies and three to five dendrites oriented in all directions, although one or two often extend mediolaterally. These results indicate that cytoarchitectonic subdivisions of the NST are distinguished by their efferent ascending connections. For each subdivision within the rostral, gustatory NST there is a correlation between the density of lingual inputs it receives and the density of pontine-projection neurons it contains. Within the rostral central subdivision, which contains the densest lingual inputs and the largest collection of PBN-projection neurons, cell types previously identified in studies with the Golgi method were found to send their axons to the PBN. The presence of two types of pontine-projection cells in the rostral central subdivision provides a structural basis for parallel information processing in the ascending gustatory system. Projections to the PBN from regions outside the NST provide opportunities for convergence, at the level of the pons, between inputs arising from gustatory/general viscerosensory subdivisions of the NST and from trigeminal sensory nuclei and the reticular formation.     

Differential projections from gustatory responsive regions of the parabrachial nucleus to the medulla and forebrain

The present study combined extracellular electrophysiology with anterograde and retrograde tracing techniques to determine efferent projections from taste responsive sites within the parabrachial nucleus (PBN). Taste activity was recorded from two distinct regions of the PBN, the waist region consisting of the ventrolateral (VL) and central medial (CM) subnuclei, and the external region, consisting of the external medial (EM) and external lateral (EL) subnuclei. Ascending and descending projections from these two regions differed. Small biotinylated dextran injections placed in taste responsive sites in the waist area produced a prominent descending projection to the medullary parvocellular reticular formation, a projection nearly non-existent from the external region. Differences in ascending projections were more subtle. Projections to the thalamus were bilateral in all cases, however, the waist region had a larger ipsilateral thalamic projection than the external region and the external region had a larger contralateral projection compared to the waist. Central nucleus of amygdala (CNA) projections from the waist area were primarily from posterior tongue responsive sites in VL and terminated in the central medial and lateral CNA subnuclei; external region projections were distributed to the capsular region of CNA. Both the external and waist region projected to substantia innominata (SI). Different efferent projections from the two gustatory responsive regions of the PBN may reflect functional specialization of PBN subnuclei. Descending projections from orally responsive sites in the waist area project to the lateral parvocellular reticular formation, a region implicated in brainstem circuitry underlying consummatory components of ingestive function. The external region, contains cells responsive to pain and oral aversive stimuli, but does not apparently contribute directly to local brainstem functions. Rather, forebrain pathways appear critical to the expression of external region functions.     

Connections of the mesencephalic locomotor region (MLR) II. Afferents and efferents

Injections of a tritiated amino acid-fluorescent dye mixture were made unilaterally into the area of the mesencephalic locomotor region (MLR). After allowing for retrograde and anterograde transport, the same site was electrically stimulated to induce locomotion on a treadmill following a precollicular-postmamillary transection. The tritiated amino acid transported anterogradely primarily was found autoradiographically to descend in the area of Probst's tract and to ascend to the centremedian nucleus (CM) of the thalamus. Neurons labeled retrogradely by the fluorescent dye in the same injection-stimulation site were observed in the substantia nigra, entopeduncular nucleus, sub- and hypothalamus and amygdala. In subsequent experiments, injections of fluorescent tracers were made into the area of Probst's tract and CM. Neurons in the mesencephalic trigeminal root, cuneiform nucleus, nucleus tegmenti pedunculopontinus (NTPP), dorsal locus coeruleus and lateral central gray were labeled from Probst's tract injections. Neurons in medial and lateral central gray, as well as NTPP, were labeled from CM injections.     

Mapping study of the parabrachial taste-responsive area for the anterior tongue in the golden hamster

The locations of taste-responsive areas within the brainstem parabrachial nucleus (PBN), an obligatory taste relay in the golden hamster (Mesocricetus auratus), were mapped in relation to cytoarchitectural boundaries. The PBN was systematically searched for multiunit neural activity in response to a taste mixture composed of 0.1 M sucrose, 0.03 M NaCl, and 0.1 M KCl applied to the anterior tongue. Taste responses were located exclusively in one of three subdivisions of the medial PBN, which is thought to be specialized for gustatory processing, and in one of six subdivisions of the lateral PBN, which is thought to be specialized for general visceral processing. Based on Nissl-stained material, both the medial and lateral PBN subdivisions in the hamster were similar to those reported for the rat PBN. The largest group of taste-responsive cells encompassed two-thirds of the central medial subdivision, while a smaller group of taste cells was exclusively located within the ventral lateral subdivision. The two taste-responsive subdivisions are separated by the superior cerebellar peduncle and contain diverse cell types. The finding that anterior tongue taste may be exclusively represented in circumscribed cytoarchitecturally defined parts of two PBN divisions suggests that taste information from the anterior tongue is required for both specific gustatory and general visceral functions.     

The organization of the efferent projections of the parabrachial nucleus to the forebrain in the rat: A retrograde fluorescent double-labeling study

The organization of the efferent projections of the parabrachial nucleus (PBN) to the forebrain has been investigated in the rat by means of combined injections of two fluorescent retrograde tracers: red fluorescent Evans Blue and a blue fluorescent mixture of 4′,6′-diamidino-2-phenylindol 2 HCl and primuline. First, the distributions of retrogradely labeled neurons in the PBN after bilateral injections of tracers in the central nucleus of the amygdala (CNA) was examined. The CNA on one side of the brain was injected with one of the tracers and the CNA on the opposite side of the brain was injected with the other tracer. Next, the distributions of labeled neurons were examined after bilateral ventral medial thalamus (VMT) injections. Finally, the retrograde labeling of the PBN was studied after combined ipsilateral injections of one tracer in the CNA and the other tracer in the VMT. After the various injections, characteristic distributions of populations of labeled neurons within the PBN were seen. Double-labeled neurons were present only after bilateral VMT injections. From this it was concluded that the PBN projections to the VMT in the rat are bilateral. Based on the relative distributions of populations of retrogradely labeled neurons in the PBN, it was suggested that the PBN projects primarily taste information to the VMT and mainly visceral information to the CNA. This transfer of information to the forebrain is discussed.     

Localization of parabrachial nucleus neurons projecting to the thalamus or the amygdala in the cat using horseradish peroxidase.

Topographical localization of parabrachial nucleus (PBN) neurons projecting directly to the thalamus or the amygdala was examined in the cat by the horseradish peroxidase (HRP) method. After HRP injection in the central nucleus of the amygdala, PBN neurons labeled with the enzyme were seen ipsilaterally in the ventral portion of the lateral PBN as well as in the medial PBN. When the HRP injections were centered on the parvocellular portion of the posteromedial ventral nucleus of the thalamus (VPMpc), HRP-labeled neurons were observed ipsilaterally in the dorsal portion of the lateral PBN as well as in the medial PBN. Within the medial PBN, the distribution of neurons projecting to the amygdala overlapped that of neurons projecting to VPMpc; the cell bodies of the former neurons, however, tended to be more elongated than the latter, and the mean of the average soma diameters of the former was significantly larger than the latter. On the other hand, in the lateral PBN no significant differences were noted between the means of the average soma diameters of neurons projecting to VPMpc and those projecting to the amygdala. The PBN neurons in the cat were presumed to transmit gustatory and general visceral information ipsilaterally to the thalamic taste region and the limbic areas in the basal forebrain.     

A subpopulation of neurons in the rat rostral nucleus of the solitary tract that project to the parabrachial nucleus express glutamate-like immunoreactivity

In rodents, gustatory information is transmitted from second order neurons in the rostral nucleus of the solitary tract (rNST) to the parabrachial nucleus (PBN) in the pons. The chemical nature of this projection is unknown. Therefore, the goal of the current study was to determine if rNST neurons that project to the PBN express glutamate-like immunoreactivity. Projection neurons were retrogradely labeled following stereotaxic injection of rhodamine-filled latex microspheres into the right PBN of seven rats while glutamate-immunoreactive (GLU-IR) structures were visualized in the same tissue using an immunoperoxidase procedure. The number of single- and double-labeled neurons located in the right (ipsilateral) and left rNST, in each of the nuclear subdivisions as well as their position along the rostral-caudal axis of the rNST was determined. GLU-IR cell bodies were located throughout the rNST. Although the rostral central subdivision contained the highest percentage (33.8%) of GLU-IR perikarya, immunolabeled neurons were most concentrated (number/area of subdivision) within the medial subnucleus. The rostral third of the rNST contained the fewest (20. 5%) and lowest density of GLU-IR cell bodies. The highest percentage of rNST neurons retrogradely labeled from the PBN were located ipsilateral (85.4%) to the pontine injection site, in the middle third of the nucleus (44.2%) and within the rostral central subdivision (52.4%). Overall, 18% of the labeled rNST projection neurons were GLU-IR. The distribution of double-labeled neurons mirrored that of the projection neurons with the largest number located in the ipsilateral rNST (84.5%), middle third of the nucleus (40.5%) and rostral central subdivision (64.7%). These results indicate that glutamate may be a main component of the ascending pathway from the rNST to the PBN. In addition, since GLU-IR neurons were located throughout the rNST and most were not retrogradely-labeled, the current results suggest that glutamate may be an important neurotrans-mitter within the medulla.     

Efferent connections of the internal globus pallidus in the squirrel monkey: I. topography and synaptic organization of the pallidothalamic projection

The objectives of this study were, on one hand, to better understand how the segregated functional pathways from the cerebral cortex through the striatopallidal complex emerged in the projections to the thalamus and, on the other hand, to compare the ultrastructure and synaptic organization of the pallidal efferents to the ventrolateral (VL) and centromedian (CM) thalamic nuclei in primates. These aims were achieved by injections of the retrograde-anterograde tracer, biotinylated dextran amine (BDA), in different functional regions of the internal pallidum (GPi) in squirrel monkeys. The location of retrogradely labelled cells in the striatum was determined to ascertain the functional specificity of the injection sites. Injections in the ventrolateral two-thirds of the GPi (group 1) led to retrograde labelling in the postcommissural region of the putamen (“sensorimotor striatum”) and plexuses of labelled fibers in the rostral one-third of the principal ventrolateral nucleus (VLp) and the central part of the CM. On the other hand, injections in the dorsal one-third (group 3) and the rostromedial pole (group 4) of the GPi led to retrogradely labelled cells in the body of the caudate nucleus (“associative striatum”) and the ventral striatum (“limbic striatum”), respectively. After those injections, dense plexuses of anterogradely labelled varicosities were found in common thalamic nuclei, including the parvocellular ventral anterior nucleus (VApc), the dorsal VL (VLd), and the rostrodorsal part of the parafascicular nucleus (PF). In the caudal two-thirds of the CM/PF, the labelled fibers formed a band that lay along the dorsal border of the complex in a region called the dorsolateral PF (PFdl) in this study. The ventromedial nucleus (VM) was densely labelled only after injections in the rostromedial GPi, whereas the dorsal part of the zona incerta was labelled in both groups. At the electron microscopic level, the BDA-positive terminals in the VLp were larger and more elongated than those in the CM but, overall, displayed the same pattern of synaptic organization. Our findings indicate 1) that some associative and limbic cortical information, which is largely processed in segregated corticostriatopallidal channels, converges to common thalamic nuclei and 2) that the PF is a major target of associative and limbic GPi efferents in monkeys. J. Comp. Neurol. 382:323-347, 1997. © 1997 Wiley-Liss, Inc.     

Intramedullary connections of the rostral nucleus of the solitary tract in the hamster

The rostral nucleus of the solitary tract (NST) figures prominently in the gustatory system, giving rise to ascending taste pathways that are well documented. Less is known of the local connections of the rostral NST with sites in the medulla. This study defines the intramedullary connections of the rostral NST in the hamster. Small iontophoretic injections of horseradish peroxidase (HRP), confined to the rostral NST, resulted in Golgi-like filling of axons that exited the NST or that interconnected cytoarchitectonic subdivisions within the NST complex. The NST efferent axons terminated sparsely in the trigeminal, facial and hypoglossal motor nuclei, but axons and endings were heavily distributed in the parvicellular reticular formation ventral to the NST. HRP injections centered in this part of the reticular formation resulted in heavy projections to the orofacial motor nuclei. Intranuclear connections, labelled after NST injections, linked NST subdivisions that receive primary afferent taste inputs to subdivisions involved in (1) projections to the preoromotor reticular formation, (2) projections to swallowing motor neurons, (3) activation of preganglionic parasympathetic neurons, and (4) general viscerosensation. In general, the connections defined in the present study provide anatomical details about the substrate for gustatory-motor and gustatory-visceral interactions.     

Projections of the parabrachial nucleus in the old world monkey

The efferent projections of the pontine parabrachial nucleus (PBN) were examined in the Old World monkey (Macaca fascicularis) using tritiated amino acid autoradiography and horseradish peroxidase histochemistry. Parabrachiofugal fibers ascended to the forebrain along three pathways: the central tegmental tract, the ventral ascending catecholaminergic pathway, and a pathway located on the midline between the medial longitudinal fasciculi. The PBN projected heavily to the central nucleus of the amygdala and the lateral division of the bed nucleus of the stria terminalis and moderately to the ventral tegmental area and the substantia nigra. Light terminal label also was present within the dorsomedial, ventromedial, lateral, supramammillary, and infundibular nuclei of the hypothalamus and the annular nucleus and the dorsal raphe nucleus within the brain stem. The overall pattern of terminal label was similar to that previously reported for nonprimate species, but several differences were notable. In monkey the projection to the ventrobasal thalamus did not coincide with the region that contains gustatory-responsive neurons. In rats, these parabrachiothalamic fibers convey gustatory activity but in the monkey these fibers may carry visceral afferent information. The projections from the PBN to the hypothalamus in the monkey were neither as widespread nor as intense as in the rat, and the monkey lacks a projection from the PBN to the frontal and insular cortices.     

A search for the cortical gustatory area in the hamster

The gustatory area was searched in the cerebral cortex of the hamster by means of a combined approach using electrophysiological, behavioral, and histological experiments. The chorda tympani (CT), which innervates taste buds on the anterior part of the tongue, projected to a confined area anterior to the middle cerebral artery and just dorsal to the rhinal fissure. The trigeminal component of the lingual nerve (LN) area was located anterodorsal to the CT area, and the glossopharyngeal nerve (GN), which innervates taste buds on the posterior part of the tongue, was posterior to the CT area. The center of the CT and GN areas belonged to the dorsal part of the dysgranular insular cortex, and the LN area was within the primary somatosensory granular cortex. Bilateral symmetrical ablations of the CT and GN areas abolished the conditioned taste aversion (to sodium saccharin) that had been acquired before ablations, indicating a role of these areas in some cognitive processes of taste perception. Injections of horseradish peroxidase conjugated with wheat germ agglutinin (WGA-HRP) in the CT and GN areas, centered in the dysgranular insular cortex, revealed that this cortical region had major fiber connections with the contralateral homotypical cortical area, ipsilateral amygdala (central, lateral and basolateral nuclei), ipsilateral parvicellular part of the posteromedial ventral nucleus of the thalamus, bilateral parabrachial nucleus, contralateral nucleus of the solitary tract, raphe nuclei, and the locus ceruleus. Conversely, injections of WGA-HRP in these target areas showed anterograde and/or retrograde transport in the similar dysgranular insular cortex and additionally in the ventral part of the granular insular cortex. The present results suggest that the cortical gustatory area of the hamster is about 1.5 × 1.5 mm in size with the topographic organization between anterior and posterior parts of the tongue, and is located mainly in the dysgranular insular cortex around the middle cerebral artery.     

Telencephalic ascending gustatory system in a cichlid fish,Oreochromis (Tilapia) niloticus

Central fiber connections of the gustatory system were examined in a percomorph fish Oreochromis (Tilapia) niloticus by means of the horseradish peroxidase (HRP), biocytin, and carbocyanine dye tracing methods. The primary gustatory areas in tilapia are the facial, glossopharyngeal, and vagal lobes of the medulla. The secondary gustatory nucleus (SGN) is a dumb-bell-shaped structure located in the isthmic region. In the SGN, there are two or three layers of neurons lining the ventromedial periphery of the nucleus and a molecular layer constituting of the major part of the nucleus. The SGN receives bilateral projections from the facial lobes and ipsilateral projections from the glossopharyngeal and vagal lobes. Ascending fibers originating from the SGN form the ipsilateral tertiary gustatory tract. A major part of the tract courses rostrally and terminates ipsilaterally in several diencephalic nuclei: the preglomerular tertiary gustatory nucleus (pTGN), the posterior thalamic nucleus, the nucleus diffusus lobi inferioris, the nucleus centralis of inferior lobe, and the nucleus recessus lateralis. The remaining small fiber bundle enters the medial and lateral forebrain bundles and terminates directly in two telencephalic regions; the area ventralis pars intermedia (Vi) and the area dorsalis pars posterior (Dp). Ascending fibers from the pTGN pass through the lateral forebrain bundle and terminate ipsilaterally in the dorsal region of area dorsalis pars medialis (dDm) of the telencephalon. Following biocytin injections into the dDm, small, round cells were labeled in the pTGN. After biocytin injections into the Vi and Dp of the telencephalon, retrogradely labeled cells were found in the ipsilateral SGN. The results show that the ascending fiber connections of the central gustatory system in the percomorph teleost tilapia are essentially similar to those of mammals. That is, the pathway from the primary gustatory areas (facial, glossopharyngeal, and vagal lobes) through the SGN and pTGN to the dDm in tilapia corresponds with the mammalian gustatory pathway from the solitary nucleus through the pontine taste areas (nucleus parabrachialis) and the thalamic relay nucleus (ventral posteromedial nucleus) to gustatory neocortices. In addition, the pathway from the primary gustatory areas through the SGN to the Vi and Dp in tilapia corresponds with the pathway from the solitary nucleus through the pontine taste areas to the amygdala in mammals. J. Comp. Neurol. 392:209–226, 1998. © 1998 Wiley-Liss, Inc.     

Differential synaptic innervation of striatofugal neurones projecting to the internal or external segments of the globus pallidus by thalamic afferents in the squirrel monkey

It is well established that the centromedian nucleus (CM) is the major source of thalamic afferents to the sensorimotor territory of the striatum in monkeys. However, the projection sites of striatal neurones contacted by thalamic afferents still remain to be determined. We therefore carried out an anatomical study aimed at elucidating the hodology of striatal neurones that receive input from the CM in squirrel monkeys. Our approach was to combine the anterograde transport of Phaseolus vulgaris-leucoagglutinin (PHA-L) or biocytin from the CM with the retrograde transport of biotinylated dextran-amine (bio-dex) or PHA-L from the internal (GPi) or external (GPe) segments of the globus pallidus. Following CM injections, rich plexuses of anterogradely labelled, thin varicose fibres aggregated in the form of bands that were confined to the postcommissural region of the putamen. On the other hand, injections into the GPe or GPi led to profuse retrograde labelling of a multitude of medium-sized spiny neurones. In cases where the injections involved the caudoventral two-thirds of the GPe or GPi, the retrogradely labelled striatopallidal cells and the anterogradely labelled thalamostriatal fibres occurred in the sensorimotor territory of the putamen. After injections into either pallidal segments, clusters of retrogradely labelled cells were in register with bands of anterogradely labelled thalamic fibres. However, electron microscopic analysis of striatal regions containing both anterogradely labelled thalamic afferents and retrogradely labelled cells revealed that terminals from the CM frequently form asymmetric synapses with dendritic shafts and spines of striato-GPi cells but rarely with those of striato-GPe cells. In conclusion, our findings demonstrate that thalamic afferents from the CM innervate preferentially striatopallidal neurones projecting to the GPi in monkeys. These results indicate that the striatopallidal neurones contributing to the “direct” and “indirect” output pathways are differentially innervated by thalamic afferents in primates. © 1996 Wiley-Liss, Inc.     

Connections of the tectum opticum in two urodeles, Salamandra salamandra and Bolitoglossa subpalmata, with special reference to the nucleus isthmi

Tectal connections were studied in two urodele species following horseradish peroxidase injections into the tectum opticum. In both species retrogradely labelled cells were observed: ipsilaterally in the corpus striatum, lateral amygdala, ventral and dorsal thalamus and nucleus of DARKSCHEWITSCH--bilaterally in the pretectal nucleus, dorsal tegmentum and nucleus reticularis medius--contralaterally in the tectum opticum and area octavo lateralis. Besides these nuclei the nucleus isthmi was bilaterally labelled. Rostral efferent projections of the tectum opticum terminated in the ipsilateral pretectal area and the ipsilateral dorsal and ventral thalamus ipsilaterally coursing to the contralateral tectum via the commissura postoptica. Caudal efferents formed the bilaterally organized tecto-bulbar tracts innervating the rhombencephalon. Comparison of the results of a series of tectal horseradish peroxidase injections differing in depth, tangential extension and location, indicated that tectal afferents from the telencephalon, the contralateral tectum opticum and the medulla were sparse and widely branching. Projections of the telencephalon and all diencephalic nuclei terminated deep in the rostral tectum opticum. Projections of the medulla terminated preferentially deep in the caudal tectum opticum. The tecto-isthmic projection was highly topographic forming a layered terminal field lateral to the nucleus isthmi. The isthmo-tectal projection innervated the whole tectum opticum on the ipsilateral side and was highly topographic. On the contralateral side the caudal part of the tectum opticum was not innervated. The isthmo-tectal fibers terminated superficially in the tectum opticum on both sides of the brain. The nucleus isthmi identified here is proposed to be homologe to that of other vertebrates.     

Direct amygdaloid projections to the superior salivatory nucleus: a light and electron microscopic study in the cat.

Amygdaloid projections to the superior salivatory nucleus (SSN) were investigated in the cat by using the anterograde and retrograde tracing techniques of horseradish peroxidase (HRP). After HRP injections were made into the lingual nerve, retrogradely labeled SSN neurons were located in the lateral tegmental field medial to the spinal trigeminal nucleus from the middle level of the superior olivary nucleus to the caudal level of the facial nucleus. These labeled neurons, triangular, oval or polygonal in shape, were small to medium-sized (12-29 microns) and formed loosely packed clusters. In further HRP studies, HRP injections were made into the amygdala and in the reticular formation containing the SSN neurons. The results suggested that the SSN receives direct afferents from the central nucleus of the amygdala with ipsilateral predominance. Final proof of such direct connections from amygdala to the SSN can be obtained only by electron microscopic study. Therefore, HRP injections were made into the lingual nerve and in the amygdala in the same animal and electron microscopic observations were carried out on the SSN. It appeared that anterogradely labeled amygdalo-tegmental fibers formed axosomatic and axodendritic synaptic contacts with retrogradely labeled SSN neurons.     

Organisation of reciprocal connections between trigeminal and vestibular nuclei in the rat.

In order to study the connection patterns between the sensory trigeminal and the vestibular nuclei (VN), injections of anterogradely and/or retrogradely transported neuronal tracers were made in the rat. Trigeminal injections resulted in anterogradely labelled fibres, with an ipsilateral preponderance, within the VN: in the ventrolateral part of the inferior nucleus (IVN), in the lateral part of the medial nucleus (MVN), in the lateral nucleus (LVN) with a higher density in its ventral half, and in the superior nucleus (SVN), more in the periphery than in the central part. Moderate trigeminal projections were observed in the small vestibular groups f, x and y/l and in the nucleus prepositus hypoglossi. Additional retrogradely labelled neurones were seen in the IVN, MVN, and LVN, in the same regions as those receiving trigeminal afferents. Morphological analysis of vestibular neurones demonstrated that vestibulo-trigeminal neurones are relatively small and belong to a different population than those receiving projections from the trigeminal nuclei. The trigeminovestibular and vestibulo-trigeminal relationships were confirmed by tracer injections in the VN. The results show that, in the VN, there is sensory information from facial receptors in addition to those reported from the neck and body. These facial afferents complement those from the neck and lower spinal levels in supplying important somatosensory information from the face and eye muscles. The oculomotor connections of the respective zones of the VN receiving trigeminal afferents suggest that sensory inputs from the face, including extraocular proprioception, may, through this pathway, influence the vestibular control of eye and head movements.     

Ascending projections from the pedunculopontine tegmental nucleus and the adjacent mesopontine tegmentum in the rat

Ascending projections from the pedunculopontine tegmental nucleus (PPT) and the surrounding mesopontine tegmentum to the forebrain in the rat are here examined by using both retrograde and anterograde tracing techniques combined with choline acetyltransferase (ChAT) immunohistochemistry. The anterogradely transported lectin Phaseolus vulgaris-leukoagglutinin (PHA-L) was iontophoretically injected into the PPT in 12 rats. Anterogradely labelled fibers and varicosities were observed in the thalamic nuclei, confirming the findings of our previous retrograde studies (Hallanger et al: J. Comp. Neurol. 262:105-124, '87). In addition, PHA-L-labelled fibers and varicosities suggestive of terminal fields were observed in the anterior, tuberal, and posterior lateral hypothalamic regions, the ventral pallidum in the region of the nucleus basalis of Meynert, the dorsal and intermediate lateral septal nuclei, and in the central and medial nuclei of the amygdala. To determine whether these were cholinergic projections, the retrograde tracer WGA-HRP was injected into terminal fields in the hypothalamus, septum, ventral pallidum, and amygdala. Numerous ChAT-immunoreactive neurons in the PPT and laterodorsal tegmental nucleus (LDT) were retrogradely labelled from the lateral hypothalamus. These cholinergic neurons constituted over 20% of those retrogradely labelled in the dorsolateral mesopontine tegmentum; the balance consisted of noncholinergic neurons of the central tegmental field, retrorubral field, and cuneiform nucleus. Following placement of WGA-HRP into dorsal and intermediate lateral septal regions, the vast majority (greater than 90%) of retrogradely labelled neurons were cholinergic neurons of the PPT and LDT, with few noncholinergic retrogradely labelled neurons in the adjacent tegmentum. In contrast, fewer cholinergic neurons were retrogradely labelled following placement of tracer into the nucleus basalis of Meynert or into the central, medial, and basolateral nuclei of the amygdala, while numerous noncholinergic neurons of the central tegmental field rostral to the PPT and of the retrorubral field adjacent to the PPT were retrogradely labelled in these cases. These anterograde and retrograde studies demonstrate that cholinergic PPT and LDT neurons provide a substantial proportion of mesopontine tegmental afferents to the hypothalamus and lateral septum, while projections to the nucleus basalis and the amygdala are minimal.     

The parabrachial nucleus and conditioned taste aversion

The parabrachial nucleus (PBN) surrounds the brachium conjunctivum in the dorsolateral pons. Although composed of numerous subnuclei, the PBN is typically organized into medial and lateral subdivisions according to their location relative to the brachium. In rodents, the medial PBN is part of the central gustatory system, whereas the lateral PBN is a component of the visceral sensory system. Lesions of the PBN disrupt conditioned taste aversion, a critically important learning mechanism that prevents the repeated ingestion of toxic food. Relevant neurobehavioral literature is reviewed to elucidate the role of the PBN in taste aversion learning.     

Thalamic connectivity of the primary motor cortex of normal and reeler mutant mice

Reeler, an autosomal recessive mutation in mice, causes cytoarchitectonic abnormalities of the cerebral cortex, which are characterized by malposition of neurons. Retrograde and anterograde transport of horseradish peroxidase (HRP) was employed to examine the reciprocal connectivity between the hindlimb area of the primary motor cortex (MI) and thalamus of normal and reeler mutant mice. In the normal mouse, most of the cells labelled after HRP injection into the hindlimb area of MI were located in the ventrolateral nucleus, the lateral division of the ventrobasal nucleus, the central lateral, paracentral and central intralaminar nuclei, and the medial division of the posterior complex. HRP reaction product anterogradely transported was also observed in the same nuclei and in the thalamic reticular nucleus. In the reeler mutant mouse, retrogradely labelled neurons and anterogradely labelled terminals were again found in the nuclei referred to above, and the distribution pattern and morphology of HRP-filled neurons were also similar to those of normal controls. The present results suggest therefore that the normal reciprocal connectivity between MI (hindlimb representation) and thalamus is preserved in the reeler mouse. That is to say, dislocated cortical neurons appropriately project to their target nuclei of the thalamus, and conversely, thalamic neurons send their axons precisely to their target cortical areas of the radially disorganized cortex.     

Forebrain projections to the rostral nucleus of the solitary tract in the hamster

The rostral nucleus of the solitary tract (NST) is the first central site of taste information processing. Specific anatomical subdivisions of the NST receive taste afferent input and contain interneurons and projection neurons that engage ascending or premotor taste pathways. The forebrain projects to the NST and can influence taste responses, but the anatomical relationship between forebrain inputs and the subdivisions of the NST and their cellular elements is not understood. To evaluate this, in this study, we used cholera toxin B (CTb) as a retrograde and anterograde marker. CTb was injected into the rostral NST to label, by retrograde transport, the sources of forebrain inputs. Cells were labeled bilaterally in the lateral and paraventricular hypothalamic nuclei, bed nucleus of the stria terminalis, central nuclei of the amygdala, and the agranular and dysgranular divisions of insular cortex. Within the medulla, labeled cells were located in the parvicellular reticular formation and spinal trigeminal nuclei. In addition, labeled cells and anterograde axonal labeling were present in the rostral NST contralateral to the injections. Injections of CTb centered in the dysgranular insular cortex, the site of most forebrain-NST cells, labeled axon endings confined to the rostral NST. These endings were concentrated in the rostral central and ventral subdivisions. Corticofugal endings in the rostral central subdivision are positioned to influence microcircuits that include taste afferent synapses, presumed inhibitory interneurons, and neurons that project to the parabrachial nucleus. The many corticofugal endings in the ventral subdivision synapse among premotor neurons that ultimately influence salivatory and oromotor outflow. Intramedullary CTb labeling after NST injection indicates that the rostral central subdivision also receives projections from the contralateral rostral NST.