Spinocerebellar neurons and propriospinal neurons in the cervical spinal cord: a fluorescent double-labeling study in the rat and the cat

Summary In the cervical spinal cord of the rat and the cat, the distributions of spinocerebellar and of descending propriospinal neurons were investigated using the retrograde fluorescent double-labeling technique. Moreover, a search was made for the presence of neurons with both ascending spinocerebellar and descending propriospinal axoncollaterals. Diamidino Yellow Dihydrochloride (DY) was injected at T2, while True Blue (TB) (in rats) or Fast Blue (FB) (in cats) was injected in the cerebellum. The distributions of labeled neurons were very similar in the rat and the cat. DY-labeled propriospinal neurons, projecting to T2 or below, were most numerous in lamina I and laminae IV to VIII. In the rat, such neurons were also present in the lateral spinal nucleus (LSN). TB- or FB-labeled spinocerebellar neurons were concentrated in the central cervical nucleus (CCN) at C1-C4, in the central part of lamina VII at C5-T1, in the medial part of lamina VI and the adjoining dorsomedial part of lamina VII at C2/C3-T1, and in Clarke's column. They were also found in lamina V at C1 and C7-T1, and in lamina VIII at all levels. In both species only very few DYTB/FB double-labeled neurons, representing neurons with branching axons, were observed; in C1-T1, only about 0,5% of all TB/FB-labeled Spinocerebellar neurons and about 0,05% of all DY-labeled descending propriospinal neurons were double-labeled. The double-labeled neurons were all located centrally in lamina VII at C5-T1, but even in that area they constituted not more than 1,5% (rat) and 4% (cat) of the labeled spinocerebellar neurons. These findings indicate that, in the cervical cord of the rat and the cat, descending propriospinal neurons and spinocerebellar neurons are to a large extent separate populations.     

Branching neurons in the cervical spinal cord: a retrograde fluorescent double-labeling study in the rat

Summary Branching neurons giving rise to ascending and descending collaterals were studied in the cervical spinal cord of the rat. After unilateral injection of two retrograde fluorescent tracers, i.e. DY.2HCl at T2 or more caudal levels and TB at C1 or more rostral levels, many DY-TB double-labeled neurons were found in C3 to C8. These neurons were located bilaterally throughout the spinal grey matter, as well as in the lateral spinal nucleus (LSN). However, no double-labeled neurons could be detected in the laminae I and II on either side. The double-labeled neurons must represent branching neurons giving rise to a collateral ascending to the rostral injection-site or above, and another collateral descending to the caudal injection-site or below. The descending collaterals were found to extend to various spinal levels, including the lumbosacral cord. However, most of them terminated at shorter distances from their parent cell bodies; thus 20% of the C3–C8 neurons projecting to C1 or above had a descending collateral reaching T2, 8% had a collateral reaching T9, and 3% a collateral reaching L2/L3. The ascending collaterals of the majority of the branching neurons passed into the most caudal part of the medulla oblongata, and about half of these collaterals reached the level of the rostral part of the inferior olive. In regard to the neurons located in the segments C5–C8, about 13% of those projecting to T2 or below distribute an ascending collateral restricted to C2–C4, while 29% of those had an ascending collateral to C1 or above.     

Neuropeptide FF in the lateral spinal and lateral cervical nuclei: Evidence of contacts on spinothalamic neurons

Neuropeptide FF (NPFF, F8Famide) is best known for its modulating effect on opioid analgesia and morphine tolerance. However, the exact mode of action of NPFF in sensory transmission is not known. We compared the distribution of NPFF-immunoreactive (ir) fibers and terminal-like thickenings with the retrograde, tracer-filled spinothalamic (ST) neurons in the lateral spinal nucleus (LSN) and lateral cervical nucleus (LCN) of rat, areas where NPFF-containing nerve terminals are abundant. We injected fluorescent latex microspheres into the ventroposterolateral thalamic nucleus and more medial thalamic nuclei, which are innervated by ST neurons. We found NPFF-ir terminal-like thickenings and fibers apposing the tracer-filled neurons in the LSN and LCN. ST neurons filled with the retrograde tracer making contacts with NPFF-ir terminal-like thickenings, were found to terminate not only in the ventroposterolateral thalamic nucleus but also in more medial thalamic nuclei. The highest number of tracer-filled ST neurons having NPFF-ir terminal-like thickenings and fibers in apposition were found at the cervical level. Our results suggest that NPFF-containing systems in the spinal cord of rat are not limited to the substantia gelatinosa, and the sensory functions of NPFF may be mediated at least partly through the modulation of the ST system. NPFF-ir contacts in the LSN and LCN might play an important role in the somatic sensory transmission system. This study shows evidence for the first time that the spinal NPFF-containing system may be involved in mechanisms that control sensory input to the supraspinal levels. Received: 11 March 1997 / Accepted: 10 September 1997     

Identification of phrenic afferents to the external cuneate nucleus: a fluorescent double-labeling study in the cat

In the cat, C5-C6 dorsal root ganglion cells related to phrenic afferents projecting directly to the ipsilateral external cuneate nucleus (ECN) were submitted to a double-labeling procedure using anterogradely transported Fast Blue and retrogradely transported Nuclear yellow. These afferents, certainly related to muscle spindles and/or Golgi tendon organs, are very few and terminate preferentially in the intermediate and rostral parts of the ECN. Our results confirm previous electrophysiological and histological studies on the participation of phrenic afferents to the spino-cuneo-cerebellar pathway ascending through the dorsal columns.     

Branching cortical neurons in cat which project to the colliculi and to the pons: a retrograde fluorescent double-labeling study

Summary The fluorescent double-labeling technique has been used to determine whether the corticopontine and the corticotectal fibers in the cat are derived from two different sets of neurons or whether they are derived from branching neurons which distribute collaterals to the pontine grey and the colliculi. After unilateral DY.2HCl injections in the pontine grey and FB injections in the ipsilateral colliculi, large numbers of FB-DY.2HCl double-labeled neurons were present in the cortex of the ipsilateral hemisphere. However, the labeled neurons in its rostral part may have represented pyramidal tract neurons which were labeled retrogradely because their fibers descended through the DY.2HCl injection area. Therefore, also DY.2HCl injections were made in the pyramid (i.e. caudal to the pons) and the cortical pyramidal tract area, containing the retrograde DY.2HCl-labeled neurons, was delineated. In the rest of the experiments only the DY.2HCl-labeled neurons in the caudal two thirds of the hemisphere (outside the pyramidal tract area) were taken into account because only these neurons could, with confidence, be regarded as corticopontine neurons. In some anterograde HRP transport experiments the trajectories of the corticotectal and the corticopontine fibers were visualized. On the basis of the findings the DY.2HCl injections in the pontine grey were placed such that they could not involve any of the corticotectal fibers passing from the cerebral peduncle to the colliculi. Thus artifactual doublelabeling of cortical neurons was avoided. However, also under these circumstances many double-labeled neurons were present in the caudal two thirds of the hemisphere. This led to the conclusion that in the cat a large proportion of the corticopontine neurons in the caudal two thirds of the hemisphere represent branching neurons which also distribute collaterals to the colliculi. The parietal (anterior part of the lateral gyrus, middle and posterior suprasylvian gyri) and the cingulate areas together contained three quarters of all labeled corticopontine neurons outside the pyramidal tract area. In the parietal areas roughly 25% of them were double-labeled and in the cingulate area 14%. However, in the visual areas 18 and 19 a much larger percentage (30–60%) was doublelabeled. In a recent study from our laboratory it was found that in the cat the pyramidal tract fibers distribute an abundance of collaterals to the pontine grey. Therefore, a large proportion of all corticopontine connections in this species appear to be established by branching neurons which also distribute fibers to other cell groups in the brain stem and the spinal cord.Abbreviations A.E. anterior ectosylvian sulcus - a.e.s. anterior ectosylvian sulcus - BC brachium conjunctivum - BCI brachium colliculus inferior - BP brachium pontis - cor. sulc. coronal sulcus - CP cerebral peduncle - CR. cruciate sulcus - CUN cuneiform nucleus - DBC decussation brachium conjunctivum - DLP dorsolateral pontine nucleus - IC inferior colliculus - inf. coll. inferior colliculus - INS. insula cortex - IO inferior olive - IP interpeduncular nucleus - LAT. lateral sulcus - l.s. lateral sulcus - MG medial geniculate body - LL lateral lemniscus - ML medial lemniscus - MLF medial longitudinal fascicle - NdG dorsal nucleus of Gudden - NLL nucleus lateral lemniscus - NRTP reticular tegmental pontine nucleus - ORB. orbital sulcus - P pyramid - PAG periaqueductal grey - P.E. posterior ectosylvian sulcus - RF reticular formation - PG pontine grey - RB restiform body - RN red nucleus - S. sylvian sulcus - SC superior colliculus - SN substantia nigra - SO superior olive - SPV spinal trigeminal complex - S.S. suprasylvian sulcus - s.syl.s. suprasylvian sulcus - S.SPL. suprasplenial sulcus - SPL. splenial sulcus - spl.s. splenial sulcus - sup. coll. superior colliculus - syl.s. sylvian sulcus - TB trapezoid body - VC vestibular complex - Vm trigeminal motor nucleus - Vs trigeminal principle nucleus - III oculomotor nucleus - IV trochlear nucleus - VI abducens nucleus - VII facial nerve - VIII vestibulo-trochlear nerve Supported in part by grant 13-46-91 of FUNGO/ZWO (Dutch Organization for Fundamental Research in Medicine)     

Spinocervical neurons and dorsal horn neurons projecting to the dorsal column nuclei through the dorsolateral fascicle: a retrograde HRP study in the cat

Summary Spinocervical cells were identified by retrograde labelling from implants of HRP in the dorsolateral fascicle after destruction of the dorsal columns. They lay in laminae III and IV throughout the cord in estimated numbers of 700, 450 and 1100 in lumbosacral enlargement, upper lumbar and thoracic cord, and brachial enlargement respectively. In the cord enlargements dendritic trees were mainly or exclusively developed dorsally, with rostrocaudal exceeding mediolateral spread, and a gradient across the dorsal horn, lateral cells showing this contrast most strongly. Dendritic spread was limited at the II/III laminar boundary. Transition occurred at the edge of the enlargements to a shape with extreme rostrocaudal elongation of perikarya and of dendritic trees in upper lumbar and thoracic segments. Axons of Spinocervical cells ascended in the most dorsal part of the fascicle, distinguishable from the larger spinocerebellar bundle lying adjacent and ventral. The initial axonal course was tortuous, with local collateral branching, the axon sometimes travelling briefly in the dorsal column. In other experiments implants were made ipsilaterally in the dorsal column nuclei after destruction of the dorsal columns. Cells were few and relatively poorly labelled, for which the reasons are discussed. Some such cells, lying in lamina IV, were similar to spinocervical tract cells and may have projected to both lateral cervical and dorsal column nuclei. Others, at the extreme lateral edge of the mid-dorsal horn, were quite different, with dendrites greatly extended rostrocaudally and primary and higher order dendrites projecting ventrally from the perikaryon.     

Cerebellar and spinal projections of the coeruleus complex in the duck: A fluorescent retrograde double-labeling study

The double fluorescent retrograde tracing technique was used to identify, within the coeruleus complex (Co complex) of the duck, the nerve cells projecting to the cerebellar cortex and to the spinal cord. This technique was also used to investigate the possibility that the cerebellar and spinal projections of the Co complex are collaterals of the same axons. In the same animal, nuclear Diamidino yellow dihydrochloride (DY) fluorescent tracer was placed into the cerebellar cortex of folia V–VII, and cytoplasmic fluorescent Fast blue (FB) dye was injected into C₃–C₄ spinal cord segments. FB labeled multipolar somata and DY fluorescent nuclei were intermingled within the dorsal caudal region of the locus coeruleus (LCo) and within the dorsal division of the nucleus subcoeruleus (dSCo). Moreover, in the LCo, a low proportion of double-labeled neurons (about 3–4% of labelings) was evidenced among single-labeled neurons. In the ventral division of the nucleus subcoeruleus (vSCo), occasional DY labeled nuclei were found, whereas FB-labeled cells were frequently present. The present findings reveal the location of the coeruleocerebellar and coeruleospinal projecting neurons within the Co complex of the duck. They are intermingled in the caudal portion of the LCo and along the rostrocaudal extent of the subjacent dSco. The LCo and the dSCo are the major source of the projections to the folia V–VII, whereas the vSCo contributes very slightly to the innervation of the cerebellar injected areas. Moreover, the double-labeling study demonstrates that in the duck a low percentage of neurons within the ventrolateral portion of the caudal region of the LCo projects both to the cerebellar cortex of folia V–VII and to C₃–C₄ spinal cord segments via collaterals. Therefore, these neurons simultaneously influence the cerebellar cortex and spinal cord. The possibility that the projections studied are noradrenergic and that they play a role in feeding is discussed. Anat. Rec. 251:392–397, 1998. © 1998 Wiley-Liss, Inc.     

Thoracolumbar sympathetic preganglionic neurons in the dorsal commissural nucleus of the male rat: an immunohistochemical study using retrograde labeling of cholera toxin subunit B

The cell morphology of sympathetic preganglionic neurons (SPNs) in the dorsal commissural nucleus was studied by the retrograde labeling technique using cholera toxin subunit B (CTb) as a tracer. A small amount of an aqueous solution of CTb was injected unilaterally into the major pelvic ganglion of the male rat. Labeled SPNs were detected immunohistochemically using anti-CTb antiserum. Most of the labeled SPNs were observed in L₁ to L₃, and a very small number in T₁₃. They were observed bilaterally in the sympathetic nuclei, such as the intermediolateral cell column, intercalated nucleus and the dorsal commissural nucleus. A loose network of longitudinally or transversely oriented SPN dendrites was located within the dorsal commissural nucleus itself. The lateral margin of the dorsal commissural nucleus was roughly demarcated by longitudinally oriented dendrites. Together with the dendrites of the SPNs of the intercalated and intermediolateral cell column, laterally oriented dendrites of the dorsal commissural nucleus converged and formed the transverse dendritic bundles in the intermediate zone that connect the dorsal commissural nucleus and the intermediolateral cell column. The transverse dendritic bundles were arranged periodically. The axons of the SPNs in the dorsal commissural nucleus traveled laterally into the transverse dendritic bundles, then turned ventrally near the intermediolateral cell column, and finally entered the ventral funiculus. After rhizotomy of the ventral roots of the upper lumbar cord, labeled SPNs were found only on the side contralateral to the rhizotomy. The dorsal commissural nucleus appears as a compact single cell column, but our results clearly show that this nucleus actually consists of two adjacent parallel columns of cells.     

Suppressive effect of vagal afferents on cervical dorsal horn neurons responding to tooth pulp electrical stimulation in the rat

The aim of the present study was to test the hypothesis that vagal afferent (VA) inputs modify the tooth pulp (TP) stimulation-evoked activity of the first cervical dorsal horn (C1) neurons via the activation of endogenous noradrenergic and serotonergic systems. In 30 anesthetized rats, the activity of 56 C1 spinal neurons and the amplitude in a digastric muscle electromyogram (dEMG, n=30) increased proportionally during TP stimulation at an intensity of 1-3.5 times the threshold for the jaw-opening reflex (JOR). The activity in 46 of these C1 neurons (82.1%) was suppressed by VA stimulation (1.0 mAx0.1 ms, 50 Hz for 30 s) of the right vagus nerve. The suppressive effects of VA stimulation on C1 spinal neuron activity were significantly reduced after intravenous administration of either the alpha-adrenergic receptor antagonist phenoxybenzamine (POB, 2.0 mg/kg and 4.0 mg/kg) or the 5-hydroxytryptamine-3 (5-HT(3)) receptor antagonist ICS 205-930 (1.0 mg/kg and 2.0 mg/kg). But the 5-HT(1/2) receptor antagonist methysergide (1.0 mg/kg and 2.0 mg/kg) had no significant effect on VA stimulation-induced inhibition of the C1 spinal neuron activity. These results suggest that VA stimulation inhibits nociceptive transmission in the C1 spinal neuron activity via the activation of both noradrenergic and serotonergic (5-HT(3)) descending inhibitory systems.     

Convergence on the same neurons in the feline ventrobasal thalamus of terminals from the dorsal column and the lateral cervical nuclei: an ultrastructural study combining orthograde degeneration and anterograde axonal transport of lectin conjugated horseradish peroxidase

After electrocoagulation of the dorsal column nuclei (DCN) and injections of wheat germ agglutinin conjugated horseradish peroxidase (WGA-HRP) into the lateral cervical nucleus (LCN), two kinds of changes in fibers and boutons were observed in the dorsolateral part of the thalamic ventroposterolateral nucleus (VPL). The axons and boutons from neurons in the DCN demonstrated dark degeneration, while the fibers and synaptic terminals from the LCN-neurons contained the characteristic needle-shaped peroxidase reaction products following incubation with tetramethylbenzidine (TMB). Occasionally dark degenerating boutons and boutons with TMB-positive reaction products showed synaptic contact with the same dendritic profiles. After consideration of the possibility of an axoaxonal transfer of the tracer it is concluded that the findings demonstrate convergence of synaptic input both from the DCN and from the LCN on the same postsynaptic VPL neurons. The present results are in accordance with earlier light microscopic and neurophysiological findings. It is also concluded that the ultrastructural technique employed in this study is well suited to reveal convergence of different afferent systems on the same postsynaptic neurons.     

大鼠脊髓白质后索内P物质受体阳性神经元的形态特征及其联系

本研究应用免疫组织化学方法和免疫荧光组织化学双标技术,观察了大鼠脊髓白质后索内的P物质(SP)受体(SPR)阳性神经元的形态特征及其联系。结果表明,脊髓白质后索内存在SPR阳性神经元,它们的胞体较小,常集中在两侧后索的中线上,呈三角形、圆形和多极形;它们的短树突在胞体周围呈放射状,但向后索表面行走的树突较直,且可达脊髓表面;在激光共聚焦显微镜下可见这些SPR阳性神经元呈NeuN阳性,但GFAP呈阴性;它们的胞体及其突起与SP、谷氨酸脱羧酶(GAD)、脑啡肽(ENK)和5-HT阳性纤维及终末形成紧密接触。上述结果说明脊髓白质后索内存在神经元,且呈SPR阳性;这些SPR阳性神经元的活动可能受到多种来源神经信号的调控。     

Afferent connections of the caudal raphe pallidus nucleus in rats: a study using the fluorescent retrograde tracers fluorogold and true-blue

Afferent connections to the caudal region of the nucleus raphe pallidus (RPa) in rats were studied using fluorogold and true-blue as tracers. Due to its ability to produce limited injection sites, true-blue proved to be more appropriate than fluorogold for studying long distance connections in a narrow structure such as the RPa. Fluorescent, retrogradely-labeled perikarya were found in the preoptic area (median, medial and lateral nuclei), hypothalamus (anterior, dorsal, lateral and posterior areas, and the peri- and paraventricular nuclei), zona incerta, central gray (dorsal, ventral and ventro-lateral), reticular formation of the brainstem, trigeminal spinal nuclei and in the spinal cord (laminae V-X at thoracic, lumbar and sacral levels). This connection pattern suggests the involvement of the RPa in autonomic, somatic and endocrine functions.     

Cytology, synaptology and immunocytochemistry of commissural neurons and their putative axonal terminals in the dorsal cochlear nucleus of the rat

The first binaural integration within the auditory system responsible for sound localization depends upon commissural neurons that connect the two symmetrical cochlear nuclei. These cells in the deep polymorphic layer of the rat dorsal cochlear nucleus were identified with the electron microscope after injection of the retrograde tracer, Wheat Germ Agglutinin conjugated to Horseradish Peroxydase, into the contralateral cochlear nucleus. Commissural neurons are multipolar or bipolar with an oval to fusiform shape. Few commissural neurons, most inhibitory but also excitatory, connect most of the divisions of the rat cochlear nuclei. The most common type is a glycinergic, sometimes GABAergic, moderately large cell. Its ergastoplasm is organized into peripheral stacks of cisternae, and few axo-somatic synaptic boutons are present. Another type of commissural neuron is a medium-sized, spindle-shaped cell, glycine and GABA-negative, with sparse ergastoplasm and synaptic coverage. A giant, rare type of commissural neuron is glycine-positive and GABA-negative, with short peripheral stacks of ergastoplasmic cisternae. It is covered with synaptic boutons, many of which contain round synaptic vesicles. Another rare type of commissural neuron is a moderately large cell, oval to fusiform in shape, immunonegative for both glycine and GABA, and contacted by many axo-somatic boutons. It contains large dense mitochondria and numerous dense core vesicles of peptidergic type. Some labelled boutons, mostly inhibitory and probably derived from commissural neurons, contact pyramidal, cartwheel, giant and tuberculo-ventral neurons. The prevalent inhibition of electrical activity in a cochlear nucleus observed after stimulation of the contralateral cochlear nucleus may be due to commissural inhibitory terminals which contact excitatory neurons such as pyramidal and giant cells. Other inhibitory commissural terminals which contact inhibitory neurons such as cartwheel and tuberculo-ventral neurons, may explain the stimulation of electrical activity in the DCN after contralateral stimulation.     

The morphology of neurons in trigeminal nucleus oralis projecting to the medullary dorsal horn (trigeminal nucleus caudalis): a retrograde horseradish peroxidase and Golgi study

This study demonstrates that trigeminal nucleus oralis, the most rostral subdivision of the spinal trigeminal nucleus, contains four morphologically distinct types of small neurons which project to the medullary dorsal horn (trigeminal nucleus caudalis) via descending intratrigeminal pathways. Using the retrograde transport of horseradish peroxidase following injections in the medullary dorsal horn, labeled small neurons with cell bodies ranging from 8-15 microns in diameter are found principally in the ventrolateral portion of the trigeminal nucleus oralis. Most neurons are labeled ipsilaterally throughout the entire rostrocaudal extent of the ventrolateral portion of the trigeminal nucleus oralis, but a few cells are also labeled contralaterally. From this aspect of the present study it can be concluded that a specific portion of the trigeminal nucleus oralis, i.e. the ventrolateral part, contains numerous small neurons which send descending projections to the medullary dorsal horn that could affect synaptic activity there. Utilizing both the methods of Golgi and retrograde horseradish peroxidase labeling four distinct types of small descending medullary dorsal horn projection neurons can be distinguished in the ventrolateral portion of the trigeminal nucleus oralis on the basis of their morphology and the distribution of their axons and dendrites. All four neuronal cell types are present throughout the entire rostrocaudal extent of the trigeminal nucleus oralis. Type I neurons are the most frequently labeled descending medullary dorsal horn projection neurons. They are concentrated in the medial 500-550 microns of the ventrolateral portion of the trigeminal nucleus oralis and display dendritic trees which occupy spherical domains approaching 300 microns in diameter. The unmyelinated axons of many of these cells arise either directly from the cell body or a primary dendrite and give rise to a single collateral within 50 microns of their site of origin. This collateral generates a fine axonal plexus within a portion of the dendritic arbor of the parent cell while the parent axon, without branching further, travels a short distance in the ventrolateral portion of the trigeminal nucleus oralis and enters a deep axon bundle. Type II neurons are the second most frequently labeled descending medullary dorsal horn projection neuron. They generate medial and lateral dendritic arbors which together span nearly the entire medial 500-550 microns of the ventrolateral portion of the trigeminal nucleus oralis. An unmyelinated axon emerges from the cell body and within 10-30 microns of its origin gives rise to two collaterals.(ABSTRACT TRUNCATED AT 400 WORDS)     

Lumbar dorsal root projections to spinocerebellar cell groups in the rat spinal cord: a double labeling study

Summary The aim of this study has been to investigate projections to spinocerebellar cell groups from lumbar dorsal root ganglia (DRGs) in the rat. The binding subunit of cholera toxin conjugated to horseradish peroxidase (B-HRP) was used to label primary afferent fibers. Spinocerebellar neurons were labeled retrogradely by Fluoro-Gold (FG). To determine the orientation of dendrites, retrogradely labeled spinocerebellar neurons were studied, following injections of wheat germ agglutinin conjugated horseradish peroxidase (WGA-HRP) into cerebellum. FG or WGA-HRP labeled neurons were found mainly in laminae V and VII, in the lateral group of lamina IX, in Clarke's column (CC) and in the dorsal funiculus. B-HRP labeled primary afferent fibers overlapping with FG labeled cells were observed at all these locations after injections of B-HRP into different DRGs. The overlap in lamina V was found mainly medially and dorsolaterally. CC was found to receive dense projections from DRGs L1–6. In the lumbar part of CC, labeling from DRGs L4–5 overlapped and was distributed over the entire mediolateral extent of the CC, whereas labeling from DRGs L1–3 was somatotopically organized and projected to successively more dorsomedial areas. The central area of lamina VII showed moderate labeling from DRGs L3–5. The lateral group of lamina IX received only smaller amounts of labeled fibers from DRGs L3–5.     

Collateralization of cerebellar efferent projections to the paraoculomotor region,superior colliculus,and medial pontine reticular formation in the rat: a fluorescent double-labeling study

Summary Collateralization of cerebellar efferent projections to the oculomotor region, superior colliculus (SC), and medial pontine reticular formation (mPRF) was studied in rats using fluorescent tracer substances. In one group, True Blue (TB) was injected into the oculomotor complex (OMC), including certain paraoculomotor nuclei and supraoculomotor ventral periaqueductal gray (PAG), and Diamidino Yellow (DY) was injected into the medial pontine reticular formation (mPRF) or pontine raphe. The largest number of single-TB-labeled (paraoculomotor-projecting) cells was observed in the medial cerebellar nucleus (MCN) and posterior interposed nucleus (PIN), whereas the largest number of single-DY-labeled (mPRF-projecting) cells was in the MCN. Double-TB/DY-labeled cells were present in the caudal two-thirds of the MCN, suggesting that some MCN neurons send divergent axon collaterals to the paraoculomotor region and mPRF. In another group, TB was injected into the SC and DY into the mPRF. The largest number of single-TB-labeled (SC-projecting) cells was in the PIN, although a considerable number of cells was observed in the caudal MCN, and ventral lateral cerebellar nucleus (LCN). Single-DY-labeled (mPRF-projecting) neurons were primarily located in the central and ventral MCN, but were also present in the lateral anterior interposed (AIN) and in the LCN. Double-TB/DY-labeled neurons were observed in the caudal two-thirds of the MCN and in the central portion of the LCN. The most significant new findings of the study concerned the MCN, which not only contained neurons that projected independently to the paraoculomotor region, SC, and mPRF, but also contained a considerable number of cells which collateralized to project to more than one of these nuclei. The possibility that the MCN projects to the supraoculomotor ventral PAG (containing an oculomotor interneuron system) and to the mPRF, which in the cat and monkey contain neural elements essential to the production of saccadic eye movements, is discussed. The anatomical findings suggest that the MCN in the rat plays an important role in eye movement.Abbreviations AI anterior interposed nucleus - AIN anterior interposed nucleus - BC brachium conjunctivum (sup. cerebellar peduncle) - dlh dorsolateral hump of the AI - dmc dorsomedial crest of the AI - IC inferior colliculus - ICP inferior cerebellar peduncle - Inf infracerebellar nucleus - L lateral cerebellar (dentate) nucleus - LCN lateral cerebellar (dentate) nucleus - M medial cerebellar (fastigial) nucleus - MCN medial cerebellar (fastigial) nucleus - MLF medial longitudinal fasciculus - mPRF medial pontine reticular formation (incl. nuc. reticularis pontis oralis and caudalis) - OMC oculomotor complex - OMN oculomotor nucleus - PI posterior interposed nucleus - PIN posterior interposed nucleus - RN red nucleus - SC superior colliculus - Vl lateral vestibular nucleus - Vs superior vestibular nucleus - Y cell group Y     

Innervation of the adult rat cerebellar hemisphere by fibres from the ipsilateral inferior olive following unilateral neonatal pedunculotomy: an autoradiographic and retrograde fluorescent double-labelling study

Summary A left cerebellar pedunculotomy was carried out in neonatal rats of different ages to deprive the left cerebellar hemisphere of its normal climbing fibre input. In control adult animals this is totally crossed and thus arises only from the contralateral (right) inferior olive. After pedunculotomy, only the left inferior olive was intact, the right being degenerated. The remaining olivocerebellar pathway was investigated using anterograde autoradiographic or retrograde fluorescent double-labelling techniques. The anterograde autoradiographic technique showed that, in these animals, the remaining left inferior olive had an aberrant climbing fibre projection which travelled via the intact right inferior cerebellar peduncle to the denervated left hemicerebellum. If the pedunculotomy was carried out at 3 days of age (P3), this aberrant projection closely mirrored the normal pathway to the opposite hemisphere; pedunculotomy at P7 produced a different pattern of projection; while if the operation was done at P10 there was no new projection. True blue (TB) and diamidino yellow (DY) were injected into the denervated (left) and normal (right) cerebellar hemispheres respectively. Retrograde transport of these tracers confirmed both the aberrant ipsilateral projection and the normal crossed projection from neurons in the remaining inferior olive. Most of the ipsilaterally projecting neurons were in the medial accessory olive. As none of them were double-labelled, it was concluded that the new projection is not a collateral of normally projecting olivary neurons, but arises from a separate population of cells. The significance of these findings in relation to earlier work on this system is discussed.     

Cholinergic projections to the anterior thalamic nuclei in the rat: a combined retrograde tracing and choline acetyl transferase immunohistochemical study

Retrograde transport of horseradish peroxidase (HRP) was combined with choline acetyltransferase (ChAT) immunohistochemistry to study cholinergic projections to the anterior thalamic nuclei in the rat. Small iontophoretic injections of HRP placed into different subdivisions of the anterior thalamic nuclear complex resulted in distinct patterns of retrograde labelling in two major cholinergic cell groups of the mesopontine tegmentum, the laterodorsal tegmental nucleus (LDTg), in which a majority of the labelled cells was located, and the pedunculopontine tegmental nucleus (PPT). After injections into the posterior subdivision of the anteroventral thalamic nucleus (AVp), double-labelled neurons were present predominantly in the ipsilateral LDTg while a smaller number was found in the PPT. In the ipsilateral LDTg, 60–70% of ChAT-positive neurons were HRP-labelled, and 90–95% of the HRP-labelled neurons were ChAT-positive. In the contralateral LDTg, 30–40% of ChAT-positive neurons were HRP-labelled. After injections in the medial subdivision of the anteroventral thalamic nucleus (AVm), the pattern of labelling in LDTg was similar to that detected after injections in the AVp. The number of double-labelled neurons in the LDTg and PPT was much lower after injections into AVm than after injections into AVp. When injections were confined to the anterodorsal thalamic nucleus (AD), no HRP-labelled cells were present in the LDTg or PPT. These results show that the LDTg and PPT are the sources of the cholinergic input to the rat anterior thalamus. The major projection from LDTg and PPT is to the AVp, whereas there is a lighter cholinergic projection to the AVm. The AD does not receive a projection from cholinergic cells in the mesopontine tegmentum.Abbreviations AChE Acetylcholinestrase - AD anterodorsal thalamic · nucleus - AM anteromedial thalamic nucleus - ATN anterior thalamic nuclei - AVm medial subdivision of the anteroventral thalamic nucleus - AVp posterior subdivision of the anteroventral thalamic nucleus - CG central gray - ChAT choline acetyltransferase - DAB diaminobenzidine tetrahydrochloride - DR dorsal raphé nucleus - f fornix - HRP horseradish peroxidase - ic internal capsule - LD laterodorsal thalamic nucleus - LDTg laterodorsal tegmental nucleus - ml medial lemniscus - mlf medial longitudinal fasciculus - mt mamillothalamic tract - NRS normal rabbit serum - PPT pedunculopontine tegmental nucleus - PT paratenial thalamic nucleus - Re reuniens thalamic nucleus - Rh rhomboid thalamic nucleus - RPn raphé pontis nucleus - scp superior cerebellar peduncle - sm stria medullaris thalami - st stria terminalis - TAAB glutaraldehyde - TRN thalamic reticular nucleus - VL ventrolateral thalamic nucleus - VM ventromedial thalamic nucleus - xscp decussation of superior cerebellar peduncle     

Cells of origin of vagal motor neurons projecting to different parts of the stomach in the rat: confocal laser scanning and electron microscopic study

Parasympathetic motor neurons in the dorsal motor nucleus of the vagus (DMV) innervate the stomach by way of the gastric and hepatic branches of the vagus nerve. To investigate whether single neurons of the DMV provide collateral innervations to various parts of the stomach, we injected the retrograde tracer Fluoro-Gold (FG) into the cardia and the retrograde tracer cholera toxin subunit b (CTb) into the antrum or the pylorus of the same animal. Both retrogradely FG-labeled and CTb-labeled neurons were found throughout the DMV. Almost all CTb-labeled neurons (97%) were double-labeled with FG after injection of FG into the cardia and CTb into the antrum, while only a few CTb-labeled neurons (11%) were double-labeled with FG after injection of FG into the cardia and CTb into the pylorus. Thus, the cardia and the antrum received collateral projections, but the pylorus received projections mainly from different neurons in the DMV. These results indicate that different neurons in the DMV activate either the cardia or the pyloric sphincter muscles. We also labeled, retrogradely, the neurons projecting to the cardia and the pylorus in the DMV with cholera toxin-conjugated horseradish peroxidase (CT-HRP) to examine their ultrastructural characteristics. Although the neurons projecting to the cardia (21.6×15.0 µm, 248.0 µm² per section) were significantly smaller than the neurons projecting to the pylorus (27.5×15.9 µm, 323.2 µm² per section), their ultrastructural appearances were similar. Both types of neurons were small-to-medium sized, round or oval in shape, and generally had a small amount of cytoplasm containing a few Nissl bodies and a round nucleus. The average number of axosomatic terminals per section was low in the neurons projecting to the cardia (2.3) and the neurons projecting to the pylorus (3.0). Almost all axon terminals contacting these motor neurons contained round synaptic vesicles and made asymmetric synaptic contacts (Grays type I).